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INTRODUCTION

TO THE

RARER ELEMENTS

BY

PHILIP E. BROWNING, Ph.D.,

Assistant Pro/tssor of Ckimistry^ Ktnt Chemical Laboratory ^

YaU University,

FIRST ED ITION .

«

FIRST THOUSAND ' - --.

NEW YORK:

JOHN WILEY & SOISPS.
London : CHAPMAN & HALL. Limited.

1903.

hi.

Iti..den foundations

j R 1920 ^L I

Copyright, 1903,

BY

PHILIP E. BROWNING.

• •• *

«

ROBBKT DRUMMOKD, PRINTER, NBW YORK.

PREFACE.

This small volume, prepared from material used by the
author in a short lecture course given at Yale University,
is intended to serve as a convenient handbook in the intro-
ductory study of the rarer elements; that is, of those
elements which are not always taken up in a general course
in chemistry. No attempt has been made to treat any part
of the subject exhaustively, but enough references have
been given to furnish a point of departure for the student
who wishes to investigate for himself. Experimental work
has been included except in the case of those elements which
are unavailable, either because of their scarcity or because
of the difficulty of isolating them.

The author has drawn freely upon chemical journals and
standard general works. In his treatment of the rare earths
he has made especial use of Herzfeld and Kom's Chemie
der seltenen Erden and Truchot's Les Terres Rates, works
which he gladly recommends. He gratefully acknowledges
the valuable assistance of his wife in preparing this ma-
terial for the press.

Nbw Haven Conn., April, 1903.

iii

JOURNALS CITED.

American Chemical Journal.

American Journal of Science.

Analyst, The.

Annalen der Chemie und Phar-
macie.

Annales de Chimie.

Annales de Chimie et de Phy-
sique.

Annalen der Physik und Chemie.

Atti dell a R. Accademia dei
Lincei, Roma.

Berichte der Deutschen che-
mischen Gesellschaft.

Bulletin de l*Acad6mie imperiale
de St. Petersbourg.

Bulletin de la Soci6t6 chimique
de Paris.

Bulletin of the U. S. Geological
Survey.

Chemisches Central-Blatt.

Chemische Industrie.

Chemical News.

Chemiker-Zeitung.

Comptes rendus de T Academic
des sciences (Paris).

Crell *s Annalen.

Engineering and Mining Journal.

Jahresbericht der Chemie.

Journal of the American Chemi-
cal Society.

Journal of the London Chemical
Society.

Journal of Physical Chemistry.

Jotimal ftir praktische Chemie.

Jotimal of the Russian Physical-
Chemical Society.

Journal of the Society of Chemi-
cal Industry.

Klaproth's Beitrage.

Kongl. Vetenskaps Academiens
Handlingar (Stockholm).

Liebig*s Annalen der Chemie.

Monatshefte ftir Chemie.

Nicholson *s Journal.

Philosophical Magazine.

Philosophical Transactions of the
Royal Society.

Poggendorff' s Annalen.

Proceedings of the American
Academy of Arts and Sciences.

Proceedings of the Royal So-
ciety (London).

Rendiconto dell* Accademia delle
Scienze Fisiche e Matematiche,
Napoli.

Science.

Sitztmgsberichte der kaiserlichen
Akademie der Wissenschaf ten.
Mathematisch - Naturwissen-
schaftliche Classe (Wien).

Zeitschrift fur analytische
Chemie.

Zeitschrift ftir angewandte
Chemie.

Zeitschrift ftir anorganische
Chemie.

INDEXES TO THE LITERATURE OF CERTAIN

ELEMENTS.

Caesitim, Rubiditmi, and Lithium, Index to the Literature of;
Fraprie. In preparation.

Cerium, Index to the Literature of (i 751-1894); Magee. Smith-
sonian Misc. Coll. (1895), No. 971.

Coltimbitim, Index to the Literature of (1801-1887); Traphagen.
Smithsonian Misc. Coll. (1888), No. 663.

Didymium, Index to the Literature of (i 842-1 893); Langmuir.
Smithsonian Misc. Coll. (1894), No. 972.

Gallitim, Index to the Literature of (1876-1903) ; ) Browning.

Germanitim, Index to the Literature of (i 886-1 903) ; >• In prepara-

Inditim, Index to the Literature of (i 863-1 903) ; ) tion.

Lanthantim, Index to the Literature of (i 839-1 894); Magee.
Smithsonian Misc. Coll. (1895), No. 971.

Lithitun, vid, Caesitim.

Niobitim or Coltimbium, vid. Coltunbium.

Platintim Metals, Bibliography of (i 748-1897); Howe. Smith-
sonian Misc. Coll. (1897), No. 1084.

Rubiditun, vid. Caesium.

Selenitim and Telluritim, Index to the Literattire of; O. A. Smith,
In preparation.

Tellurium, vid. Selenium.

Thallitim, Index to the Literature of (1861-1896) ; Doan. Smith*
sonian Misc. Coll. (1899), No. 11 71.

Thoritim, Index to the Literature of; Jottet. Smithsonian Misc.
Coll. In press.

Titanitim, Index to the Literature of ( 1783-187 6); Hallock. An-
nals of the N. Y. Academy of Sciences (1876), i, 53.

Uranium, Index to the Literature of (i 789-1885) ; Bolton. Smith*
sonian Report for 1885, Part i, 915.

Til

viii INDEXES TO THE UTERATURE OF CERTAIN ELEMENTS.

Vanaditmi, Index to the Literature of (i 801-187 7); Rockwell,
Annals of the N. Y. Academy of Sciences (1879), i, 133.

Yttritim Group, Index to the Literature of the Rare Earths of;
Dales. In preparation.

Zirconitim, Index to the Literature of (i 789-1 898); Langmuir
and Baskerville. Smithsonian Misc. Coll. (1899), No. 11 73.

Attention is called also to the following monographs:

Die Chemie des Thoriums; Koppel. Sammlung chemischer Vor-
trage, Band VI. Pub. by Ferd. Enke, Stuttgart, 1901.

Studien iiber das Tellur; Gutbier. Pub. by C. L. Hirschfeld, Leip-
zig, 1902.

La Chimie de L'Uranitmi (1872-1902); Oechsner de Coninck.
Pub. by Masson et Cie., Paris, 1902.

Die analytischer Chemie des Vanadins ; Valerian von Klecki. Pub.
by Leopold Voss, Hambtirg, 1894.

THE RARER ELEMENTS.

C-ffiSIUM, Cs, 133.

Discovery. Caesium was discovered in i860 by Bun-
sen and Kirchhoff while they were engaged in the spectro-
scopic examination of a mother-liquor from the waters of
Diirkheim spring (Pogg. Aimal. cxiii, 337; Chem. News 11,
281). After the removal of the strontiimi, calciimi, and
magnesiimi, by well-known methods, and of the lithium
as far as possible by ammoniimi carbonate, the mother-
Kquor was tested, and gave, in addition to the potassium,
sodium, and lithium lines, two beautiful blue lines never
before observed, near the strontium blue lines. Bunseii
gave the name Caesiimi to the newly discovered element,
from the Latin caesius, the blue of the clear sky.

Occurrence.. Caesium is found in combination as
follows :

(i) In minerals:
Pollucite, HjCs^Al^CSiOa)^, contains 31-37%* CSjO.

Z^/?ictoto^,LiK(Al(OH,F)2)-Al(SiO,)„containso,2-o.7%Cs,0.
Beryl, Be3Al3(Si03)a, contains 0-3% CS2O.

(2) In certain mineral waters, among which are Durk-
heim (i liter contains about 0.21 mg. RbCl and 0.17 mg.
CsCl), Natiheim, Baden-Baden, Frankenhausen, Kreuz-
nacher, Bourbonne les Bains, Monte Catino, Wheal Clifford.

Extraction. Of the methods in use for the extraction
of caesium the following may serve as examples:

* In the tabulation of percentages the nearest whole numbers have
generaJljr been used in this book.

« THE RARER ELEMENTS.

(i) From poUucite. The finely powdered mineral is
decomposed on a water-bath with strong hydrochloric acid.
To the acid solution antimony trichloride is added, which
precipitates the double chloride of antimony and caesium
(3CSCI • 2SbCl,) (Wells, Amer. Chem. Jour, xxvi, 265).
Or the acid solution may be treated with a solution of lead
chloride containing free chlorine. This precipitates a
double chloride of caesitun and tetravalent lead (2CSCI • PbCl J
(Wells, Amer. Jotir. Sci. [3] xlvi, 186).

(2) From pollucite or lepidolite. The mineral is heated
with a mixttire of calcitun carbonate and calcitun chloride,
and the fused mass is cooled and extracted with water.
The liquid is then evaporated to a small voltune, and sul-
phuric acid is added to precipitate the calcium as the sul-
phate. After filtration, evaporation is continued until the
greater part of the hydrochloric acid has been expelled.
Sodium or ammonitun carbonate is then added to complete
the removal of the calcium salt. Upon the addition of
chloroplatinic acid the caesitun and rubiditun are precipi-
tated as the salts of that acid. By the action of hydrogen
upon these salts the platintun is precipitated, while the
caesitun and rubiditun chloridgp are left in solution.

(3) From lepidolite. The mineral is decomposed by
heating with a mixture of calcitun fluoride and sulphuric
acid {vid. Experiment i).

The Element. A. Preparation. Elementary caesium
may be obtained (i) by heating caesitun hydroxide with
aluminum to redness iri a nickel retort (Beketoff, Bull.
Acad. Petersburg iv, 247) ; (2) by heating caesitun hy-
droxide with magnesium in a current of hydrogen (Erd-
mann and Menke, Jour. Amer. Chem. Soc. xxi, 259, 420);
(3) by heating caesium carbonate with magnesium in a
current of hydrogen (Graefe and Eckardt, Zeitsch. anorg.
Chem. XXII, 158).

B, Properties, Caesium, the most positive of the metals,

is silvery white and soft. It takes fire qtiicldy in the air,
burning to the oxide. It melts at 26° C. Like the other
alkaline metals it decomposes water. Determinations of
its specific gravity range from 1.88 to 2.4.

Compounds. A. Typical forms. The following are
typical compounds of caesium:
Oxide, CSjO.
Hydroxide, CsOH.
Carbonates, Cs,CO,; CsHCO,.
Chloride, CsCl.
Double chlorides, AgCl-CsCl; AgCl-2CsCl; HgCl,-CsCl;

HgCl,.2CsCl; HgCl,-3CsCl; 2HgCl,.CsCl; sHgCl,CsCl;

PbCl, -20801; PbOl, -40801; PbOlj-OsOl; 2Pb01,-0s01;

sBiOlj-sOsOl; Bi01,-30s01; 0u01,-20s01; 0u01,-20s01+

2H,0; 20u01,-30s01+2H,O; 0u01,0s01; 0u,01,0s01;

Ou,01,-30s01; 0u,Clj-60s01+2H,O; 0d01,-20s01;

OdOlj-CsOl; 2As01,-30s01; 2Sb01, • s^eSCl ; Sn01,-0s01;

Fe,01,-60s01; O0OV3OSCI; 0oCl,-20s01; 0o01,-0s0lH-

2H,0; Ni01,.20s01; NiClj-OsOl; Mn01,.20s01;

2Mn01, - 20sOH- sH,0 ; MnOl, • aCsQ -l-jHjO ; Mn01,0s01

+ 2H,0 ; MnOl, • 20s01 + H,0 ; ZnOl, - '^sCl ; ZnOl, • 20s01 ;

Mg01,0s01 + 6H,0; Au01,-0s01; Au01,-0s01+o.sH,O;

PtOl, -20801; Pt01,-20s01; PdOl, -20801; Te01,-20801;

T101,-3Cs01+H,0; T101,-20801; TlOl, • 20sOH- H,0 ;

2T101,-30s01.
Bromides, CsBr; OsBr,; OsBr,.
Double bromides, HgEr, - OsBr ; HgBr, - 20sBr ; HgBr, - sOsBr ;

2HgBr,-0sBr; PbBr,-40sBr; PbBr,-OsBr; 2PbBr,-0sBr;

OuBr, - 2 OsBr ; OuBr, - OsBr ; OdBr, • 30sBr ; OdBr, - 20sBr ;

OdBr, - OsBr ; 2A8Br, - 308Br ; OoBr, - sOsBr ; OoBr, - 20sBr ;

NiBr, - OsBr ; ZnBr, - 30sBr ; ZnBr, - 208Br ; MgBr, - OsBr +

6H,0; AuBr.-OsBr; TeBr,-20sBr; 2TlBr, • 30sBr ;

TlBr,-OsBr,
Iodides, Osl; Osl,; Osl,.
Double iodides, HgI,-OsI; Hgl,-208l; Hgl,-30sl;

THE RMRER ELEMENTS.

2HgI,CsI ; 3HgI,. 2CsI ; Pbl,. Csl ; Cdl,- sCsI ; Cdl,- 2CsI;
CdI,CsH-H,0; jAsI.-jCsI; CoI.-aCsI; ZnI,-3CsI:
ZnI,-2CsI; TeI,-2CsI; Tll,-Csl.
Mixed halides, HgCs,Cl,Br.i HgCs,CI,Br,: HgCsClBr,;
Hg.CsClBr,,; HgCs,Br,I,; HgCs,Br,I,; HgCsBrI,;
HgCs,Cl,I,; PbCs/ClBr),; PbCs(ClBr),; Pb,Cs(ClBr),.
I Double fluorides, 2CaF • ZrF, ; CsF ■ ZrF, + H,0 ; 2CsF • jZrF, +

2H.O.

' lodates, CsIO,; 2CsI0,-ip.; 2CsI0,I,0, + 2HI0,.
Nitride, CsN, (Jour. Amer. Chem. Soc. XX, 225).
Nitrates, CsNO.; 3CsN0.-Cs(N0.), + H,0.
[ Sulphates, Cs,SO,; CsHSO,; C5,S,0,; Cs,0-8S0,.
Alums, CsAl(S0J, + i2H,0; Cs,SO,-Mn,{SO,), + 24H,0;

Cs,SO, ■ Ti,0, ■ 3SO. + 24H,0.
Fluosilicate, Cs,SiP,.
Chromates, Cs,CrO.; Cs,Cr,0,.
' Chloit)platinate, CsPtClj.

B. Characteristics. With few exceptions the caesium
compounds are soluble in water. They closely resemble
the potassium and rubidium compounds, being for the
most part isomorphous with them. A comparison of the
solubilities of the alums and also of the chloroplatinates
[ of the three elements, at a temperature of I5°-I^° C,
f follows :

100 parts of water will dissolve
CsAKSO,), +12HP, o.eaparts; Cs,PtCl„ 0.18 parts.
RbAl{S0,), + i2H,0, 2.30 " Rb,PtCl„ 0.20 "
KA1(S0,), +12H.O, 13.50 " K,PtCl„ 2.17 "
I Among the important insoluble salts are the chloroplati-
nate (Cs,PtCl,), the alum (CsAKSO,), + I2H,0), and the
double chlorides with tetravalent lead (PbCl, -aCsCl),
tetravalent tin f2CsClSnCl,?), and trivalent antimony
(3CsCl-2SbCl,). The salts of cesium color the flame
[ violet. The spectrum shows two sharply defined lines
[ in the blue, designated on the scale as Csa and C^.

RUBIDIUM, S

Estimation, Separation, and Experimental Work. Vid. Ru-
biditun.

RUBIDIUM, Rb, 85.4.

Discovery. Rubidium was discovered by Bunsen
and Kirchhoff in 1861, by means of the spectroscope, in
the cotirse of some work upon a lepidoUte from Saxony
(J. B. (1861), 173; Chem. News iii, 357). The alkaline
salts had been separated by the usual methods and pre-
cipitated with platinic chloride. The precipitate, when
examined with the spectroscope, showed at first only the
potassium lines. When it had been boiled repeatedly
with water, however, the residue gave two violet lines
situated between the strontiimi blue line and the potas-
siimi violet line at the extreme right of the spectnmi.
These increased in strength as the boiling continued, and
with them appeared several other lines, among which
were two almost coincident with the potassium red line (a)
at the extreme left. These lines, observed for the first
time, marked the discovery of an element ; because of their
color Bunsen gave it the name Rubidiimi, from the Latin
rubidus, the deepest red.

Occurrence. Rubiditmi, like caesium, is widely distrib-
uted, but in very small quantities. It is fotmd

(i) In minerals:

I
LepidoUte,'^ RgAKSiO,),, contains 0.7-3.0% Rb20.

Leucite, KAKSiO,)^,

Spodtmiene , LiAl (SiO,) 2,
Triphylite, Li (Fe, Mn) P0„
LithiophiUte, Li(Mn,Fe)PO„
Camallite, KMgClg • 6H2O,
Mica and orthoclase contain

traces

* The more important mineral sources are indicated by italics.

THE RARER ELEMENTS.

(2) In certain mineral waters, among which are the
following: Ungemach, Ems, Kissingen, Nauheim, Selters,
Vichy, Wildbad, Kochbrunnen (Wiesbaden), Durkheim,

(3) In beet-root, many samples of tobacco, some coffee
I and tea, ash of oak and beech, crude cream of tartar,

potashes, and mother-liquor from the Stassfurt potassium
; salt works.

Extraction. Rubidium may be extracted with ctesium
I from lepidolite {vid. Extraction of Ccesium).

The Element. -4. Preparation. Elementary rubidium
may be obtained (i) by heating the charred tartrates to a
white heat (Bunsen) ; (2) by reducing the hydroxide or the
carbonate with magnesium (Winkler, Ber. Dtsch. chem.
Ges. XXIII, 51); (3) by reducing the hydroxide with alumi-
num (Beketoff).

B. Properties. Rubidium is a soft white metal which
melts at 38° C. It takes fire in the air, burning to the oxide.
It decomposes water. Its specific gravity Is 1.52.

Compounds. A. Typical forms. The following are
typical compounds of rubidium :
Oxide, Rb,0.
Hydroxide, RbOH.
Carbonates, Rb,CO.; RbHCO,.
Chloride, RbCl.

Double chlorides, HgCl,'2RbCl; HgCl,'2RbCH-2H,0;
' 2HgCl, ■ RbCl ; 4HgCl, ■ RbCl ; PbCl, - 2 RbCl ; 2 PbCl, ■ RbCl ;

PbCl3'2RbCl + o.5H,0; BiClj^eRbCl; BiCl,-RbCH-

4H,0; CdCl,-2RbCl; 2AsCl,-3RbC!; 3SbCl3-5RbCl;

aSbClj ■ 3RbCl ; SbCl, - RbCl ; 2SbCI, ■ RbCl + H,0 ;

MnCl,-2RbCl + 2H,0;ZnCl,'2RbCl;MgCl,'RbCl + 6H,0;

AuCl, - RbCl ; TeCl, ■ 2 RbCl ; TlCl, ■ 3 RbCl + Hp ;

TlCla-2RbCl + H,0.
Chlorate, RbClO,.
Perchlorate, RbClO..
Bromides, RbBr; RbBr..

RUBIDIUM. 7

Double bromides, 2PbBr2.RbBr; PbBr,-2RbBr+o.sH,0;

2 AsBr, . sRbBr ; 2SbBr3 • aRbBr ; AuBr, • RbBr ;

TeBr,.2RbBr; TlBrj-sRbBr + HaO; TlBr, • RbBr + H,0.
Iodides, Rbl ; Rbl,.
Double iodides, AgI-2RbI; Pbl3.RbI + 2H20; 2AsI,.3RbI;

2Sbl3 . 3RbI ; Tel, • 2RbI ; TII3 • Rbl + 2H2O.
lodates, RblO,; RblOj-HIO,; RbI03.2HI03.
Nitride, RbN3.

Nitrates, RbN03; 3RbN03-Co(N03)3 + H20.
Cyanide, RbCN.

Sulphates, Rb^SO,; RbHSO^; RbjS^O,; Rb20.8S03.
Alums, RbAl(S0j2 + 1 2H3O ; RbFeCSOJ^ + 1 2H2O ;

RbCr(S0,)3 + 12H2O ; Rb^SO, .Ti303 • 3SO3 + 24H2O.
Chloroplatinate, Rb^PtCle.
Silicofluoride, RbjSiFe.

jB. Characteristics. The rubidium compounds are very-
similar to those of potassium and caesium {vid. Caesium).
Among the important insoluble salts are the perchlorate
(RbClOJ, the silicofluoride (RbjSiFe), the chloroplati-
nate (Rb^PtCle), the bitartrate (RbHO^C.Hp,), and the
alums (RbAl(S0,)2 + 12H2O and RbFe(S0,)2+ 12H2O).
The salts of rubidium color the flame violet. The spec-
trum gives two lines in the violet to the right of the caesium
lines (Rba and Rb^), also two lines not so distinct in the
dark red (Rb^ and Rb5), near the potassium red line, at
the left of the spectrum.

Estimation of Caesium and Rubidium. Caesium and ru-
bidium may be estimated in general by the methods
applied to potassium. They are usually weighed as the
normal sulphates, after evaporation of suitable salts with
sulphuric acid and ignition of the products ; other methods,
however, such as the chloroplatinate and chloride methods,
are possible. They may also be weighed with a fair degree
of accuracy as the acid sulphates, after evaporation with
an excess of sulphuric acid, and heating at 250^-270° C.

8 THE RARER ELEMENTS.

until a constant weight is obtained (Browning, Amer.
Jour. Sci. [4] XII, 301).

Separation of Csesitixn and Rubidium. These metals belong
to the alkali group. From sodium and lithium they
may be separated (i) by chloroplatinic acid, with which
they form insoluble salts; and (2) by altunintmi sulphate,
with which they form difficultly soluble alums. From
potassitmi they may be separated by the greater solubility
of the potassitim altim and chloroplatinate in water.*

Caesitmi and rubiditmi may be separated from each
other (i) by the difference in solubility of the chloroplati-
nates;* (2) by the difference in solubility of the altmis;*
(3) by the formation of the more stable and less soluble
tartrate of rubidium; and (4) by the solubility of caesium
carbonate in absolute alcohol. Probably the most satis-
factory methods, however, are those suggested by Wells;
they depend upon the insolubility of the following salts:
caesium double chloride and iodide (CsCl,!) (Amer. Jotir.
Sci. [3] XLiii, 17), caesium-lead chloride (Cs2PbCle) (ibid.
[3] XLVi, 186), and caesitmi-antimony chloride {Cs^hjZl^
(Amer. Chem. Jour, xxvi, 265).

EXPERIMENTAL WORK ON CESIUM AND

RUBIDIUM.

Experiment i. Extraction of ccesium and rubidium salts
from lepidolite. Mix thoroughly in a lead or platinum
dish 100 grm. of finely grotmd lepidolite with an equal
amotmt of powdered fiuorspar. Add 50 cm.' of com-
mon sulphuric acid and stir until the mass has the
consistency of a thin paste. Set aside in a draught hood
until the first evolution of ftmies (SiF^ and HF) has nearly
ceased. Heat on a plate or sand-bath at a temperature
of 200^-300° C. tmtil the mass is dry and hard. Pulverize

* Vid. page 4.

EXPERIMENTAL IVORK ON Cy€SIUM AND RUBIDIUM. 9

and extract with hot water until the washings give no
precipitate on the addition of ammonium hydroxide to
a few drops. Evaporate the entire solution to about
I GO cm.* and filter while hot to remove the calcitun sul-
phate. Set the clear filtrate aside to crystallize. The
crystals, consisting of a mixture of potassixim, caesium,
and rubiditmi alums, with some lithium salt, should be
dissolved in about loo cm.' of distilled water, and allowed
to recrystallize. This process of recrystallization should
be repeated until the crystals give no test before the spec-
troscope for either lithium or potassium. The amotmt of
caesium and rubidium alimis obtained will of course vary
with the variety of lepidolite used. An average amotmt
of the mixed alums of potassitmi, caesium, and rubidium
from the first crystallization would be lo grm. The pure
caesium and rubiditmi alums finally obtained should be
about 3 grm. (Robinson and Hutchins, Amer. Chem. Jour.
VI, 74). Lithium may be extracted from the mother-liquor
{vid. Experiment 12).

Experiment 2. Preparation of ccBsium and rubidium
sulphates (CSgSO^; RbjSOJ. Dissolve in water a crystal
of the caesium and rubidium alums obtained from lepido-
lite, add a few drops of.ammonitmi hydroxide, and boil.
Filter off the altmiinum hydroxide and evaporate the
filtrate to dryness. Ignite tmtil the ammonium sulphate
is removed, dissolve in a few drops of water, filter, and
evaporate to dryness. Sulphates of caesitmi and rubidium
will remain.

Experiment 3. Preparation of the carbonates of ccBsium
and rubidium (CSjCOg ; RbjCOg) . Dissolve in water a crystal
of caesium and rubiditmi alums obtained from lepidolite,
add an excess of barium carbonate, and boil. Filter off
the altmiina, barium sulphate, and excess of barium
carbonate. Pass a little carbon dioxide through the
clear filtrate and boil to remove traces of bariimi salt.

lo THE RARER ELEMENTS.

Filter. Carbonates of caesitim and rubiditim will remain
in solution.

Experiment 4. Formation of the dotible chloride of
ccBsium and tetravalent lead (2CsCl2'PbCl^). To a few
cm. ' of a one per cent, solution of a caesium salt add a few
drops of the reagent obtained by warming lead dioxide
with hydrochloric acid and allowing the solution to stand
until cool. Make a similar experiment, using a rubiditim
salt in place of the caesitim salt. Note the absence of pre-
cipitation in this case.

Experiment 5. Precipitation of the double chloride of
ccBsium and antimony (3CsCl-2SbCl3). To a few cm.' of
a one per cent, solution [oi a caesium salt add some anti-
mony trichloride in solution and evaporate to a small
volume. The double chloride will be precipitated on cool-
ing. Repeat the experiment, using a rubidium salt. Note
the absence of precipitation in this case.

Experiment 6. Precipitation of the double salt ccBsium
chloride and stannic chloride (2CsCl-SnClJ. Make an ex-
periment similar to Experiment 5, using stannic chloride
in the place of antimonious chloride. Note the separa-
tion of the double chloride on cooling. Make a similar
experiment, using a rubidium salt.

Experiment 7. Precipitation of the chloroplatinates of
ccBsium and rubidium (CSjPtClei RbjPtCle). To a few
cm." of a solution of a caesium salt add a few drops of a
solution of chloroplatinic acid. Make a similar experiment
with a solution of a rubidium salt.

Experiment 8. Separation of ccesium from rubidium.
Apply the information gained in the foregoing experi-
ments to the separation of caesium from rubidium.

Experiment 9. Flame tests for ccesium and rubidium.
Dip the end of a platinum wire into a solution of a caesium
salt and test the action of the flame of a Btmsen btuner
upon it. Repeat, using a rubidium salt.

LITHIUM. 1 1

Experiment lo. Spectroscopic tests for c cesium and
rubidium. Test solutions of caesium and rubidixim salts
before the spectroscope. Note the twin blue lines of the
caesium spectrum and the twin violet lines of the rubiditmi*

Experim£nt ii. Negative tests of ccesium and rubidium.
Note that hydrogen sulphide, ammonitmi sulphide, and
ammonium carbonate give no precipitates with salts of
caesium and rubidium.

LITHIUM, Li, 7.03.

Discovery. In 181 7 Arfvedson, working in Berzelius's
laboratory upon a petalite from Uto, Sweden, discovered
an alkali which he fotmd to differ from those already known
in the following particulars: (i) in the low fusing points
of the chloride and sulphate; (2) in the hydroscopic char-
acter of the chloride ; and (3) in the insolubility of the car-
bonate. In his analysis of the mineral it had remained
associated with sodium, not being precipitated by tartaric
acid. To the newly discovered element the name Lithium
was given, from XiSos^ stone, because it diilered from
sodium and potassitim in having a mineral rather than
a vegetable origin (Ann. der Phys. u. Chem. (181 8), xxix,
229; Ann. Chim. Phys. [2] x, 82). It has since been found,
however, not only in the mineral kingdom, but in the
vegetable and animal kingdoms also.

Occurrence. Lithitmi is found combined as follows :

(i) In minerals:

Petalite, LiAlCSi^Og),, contains 2-5% Li^O.

Spodumene, LiAKSiO^,, ** 4-8%

Lepidolite, R,Al(SiO,)3, '' 4-6%

Zinnwaldite, (K,Li)3FeAl3Si,0,e(OH,F)„ ' ' 3-4%
Cryophyllite, complex silicates, vid. Zinnwaldite, contains
4-5% LiaO.

1 1

( c

THE RARER ELEMENTS.

Polylithionite, complex silicates, vid. Zirmwaldite, contains^

about 9% Li,0.
Beryl, Bej^l^CSiO,),, contains o-i% Li,0.

Triphylite. Li(Fe,Mn)PO„ " 8-9% "

Lithiophilite, Li(Mn,Fe)POj, " 8-9% "
Atnblygonite, Li(AIF)PO„ " 8-10% "

Small amounts of lithium are found also in some varie-
ties of tourmaline, in epidote, muscovite, orthoclase, and
psilomelane.

(2) In certain mineral waters, among which are Durk-
heim, Kissingen, Baden-Baden, Bilin, Assmannshausen,
Tarasp, Kreuznach, Salzschlirf, Aachen, Selters, Wildbad,
Ems, Homburg, Karlsbad, Marienbad, Egger-Franzen-
bad. Wheal Clifford.

{3) In seaweed, tobacco, cacao, coffee, and si^ar-
cane; in milk, human blood, and muscular tissue; in me-
teorites. It has been detected also in the atmosphere of
the sun.

Extraction. Lithium may be extracted from mineralai
by the following methods:

(1) From triphylite or lithiophilite. The coarsely ground
mineral is dissolved in hydrochloric acid to which nitric'
acid is gradually added, and the solution obtained is treated
with a sufficient amount of ferric chloride to unite with all
-the phosphoric acid present. This solution is evaporated
to dryness and the residue is extracted with hot water.
The extract thus obtained is treated with barium sulphide,
to remove the manganese and the last traces of iron. The:
barium is removed by sulphuric acid, and the filtrate
evaporated with oxalic acid and ignited. The alkalies'
remain as carbonates (Muller).

Lithium may be separated from the other alkalies by
treating the mixed carbonates with water, lithium carbonate
being compantively msoluble.

(2) From lepidolite {or any other silicate). The mineral

lU

i

LITHIUM. 13

melted at red heat in a crucible, the melted mass is cooled
rapidly in water and pulverized. Sufficient water is added
to give the material the consistency of paste. Hydrochloric
acid of specific gravity 1.2, equal in weight to the weight
of the mineral taken, is gradually added, with stirring.
The mass is allowed to stand for twenty-four hotirs. It is
then heated again to about 100° C, with stirring, and a
second portion of acid equal to the first is added. Upon
several hours' heating the silica separates in the form of
powder, and after treatment with nitric acid to oxidize
the iron, the soluble material is separated by filtration from
the silica. The filtrate is heated to the boiling-point and
treated with soditim carbonate, which precipitates iron,
altimintim, calcium, magnesium, manganese, etc. These
are removed by filtration, and the liquid is evaporated to
a small voltime and filtered again if necessary. Lithitim
carbonate is precipitated by more sodium carbonate
(Schrotter) .

The Element. A, Preparation. Elementary lithium
may be obtained by subjecting the fused chloride to elec-
trolysis. Because of its volatility it cannot, like sodium
and potassitun, be prepared by heating the carbonate.

B. Properties. Lithitim is a metallic element which has
a silvery-white luster and which oxidizes in the air, though
more slowly than potassium and sodium. It decomposes
water at ordinary temperatures, and is light enough to
float in petroleum. Its melting-point is 180° C. ; its specific
gravity is 0.59.

Compounds. A. Typical forms. The following are
typical compounds of lithitun:

Oxide, LijO.
Hydroxide, LiOH.
Carbonate, LijCO,.
Chloride, LiCl.
Chlorate, LiClO. + o.sHjO.

THE Rj4RER ELEMENTS.

Perchlorate, LiC10. + 3H,0.

Bromide, LiBr.

Bromate, LiBrO,.

Iodide, LiI + 3H,0.

lodate, LiIO, + o.sH,0.

Periodate, UIO,.

Fluorides, LiF; LiF-HF.

Nitride, LiN,.

Nitrite, LiNO, + o.5H,0.

Nitrate, UNO,.

Sulphide, Li,S.

Sulphite, LijSO,,

Sulphates, Li,SO,; KLiSO,; NaLiSO^; etc.

Phosphates, LiH.PO.; Li,PO, + o.5H,0: Li,P,0,.

Carbide, Li^C,.

Silicofiuoride. LijSiF,4-2H,0.

B. Characteristics. Most of the salts of lithium are
easily soluble in water; the principal exceptions are the
carbonate and the phosphate, which are difficultly soluble.
Lithium resembles sodium more closely than it resembles
the other alkalies, in that it does not form an insoluble
chloroplatinate, nor a series of alums. The nitrate and
the chloride are soluble in alcohol. The compounds of
lithiimi color the flame brilliant crimson.

Estimation, Lithium is usually weighed as the sul-
phate or chloride.

Separation. Lithium may be separated from the other
members of the alkali group (i) by the ready solubility of its
chloride in amyl alcohol (Gooch, Amer. Chem. Jour, ix, 33);
(2) by the solvent action of absolute ethyl alcohol upon
the chloride; (3) by the insolubility of the phosphate;
and (4) by the comparative insolubihty of the carbonate.

EXPERIMENTAL IVORK ON UTHIUM. 1$

EXPERIMENTAL WORK ON LITHIUM.

Experiment 12. Extraction of lithium salts from trp-
phylite or lithiophilite. Dissolve 25 to 50 grm. of finely
powdered mineral in common hydrochloric acid, add
sufficient nitric acid to oxidize the iron, and enough ferric
chloride to combine with all the phosphoric acid present.
Evaporate to dryness and extract with hot water. Treat
the extract with barium hydroxide in slight excess. Filter,
add sulphuric acid to complete precipitation of barium
sulphate, and filter again. Convert the sulphates present
into carbonates by the careful addition of barium carbonate,
filter, acidify the filtrate with hydrochloric acid, evaporate
to dryness, and extract the lithitim chloride with alcohol.

(Lithium salts may be extracted also from the mother-
liquor after the extraction of caesitim and rubidium salts
from lepidolite. The liquor is treated with barium car-
bonate in excess and is then boiled and filtered. The
filtrate is acidified with hydrochloric acid, evaporated to
dr3niess, and extracted with alcohol.)

Experiment 13. Precipitation of lithium phosphate
(LijPO^) . To a solution of a lithitmi salt add sodium phos-
phate in solution.

Experiment 14. Precipitation of lithium carbonate
(Li2C03). To a few drops of a concentrated solution of a
lithium salt add sodium carbonate in solution.

Experiment 15. Solvent action of alcohol upon lithium
salts. Try the action of ethyl or amyl alcohol upon a little
dry lithitim nitra,te or chloride.

Experiment 16. Flame and spectroscopic tests for lithium.
(a) Dip a platinum wire into a solution of a lithitim salt
and hold in a Btmsen flame. Note the color.

(6) Observe the hthium flame by means of the spectro-
scope. Note the bright crimson line between the potas-
sium and sodium lines.

THE R^RER ELEMENTS.

* Experiment tj. Negative tests of lithium salts. Note
that hydrogen sulphide, ammonium hydroxide, ammonium
carbonate acting upon dilute solutions, and chloroplatinic
acid give no precipitate with lithium salts.

BERYLLIUM OR GLUCmXJM, Be or Gl, 9.1.

Discovery. In the year 1 797, Vauquelin discovered beryl-
lium or glucinum in the mineral beryl (Ann. de Chim. xxvi,
155). After having removed the silica in the usual manner,
he precipitated with carbonate of potassium, and treated the
precipitate with a solution of caustic potash. The greater
part of the precipitate dissolved, leaving a residue which he
found to consist of a small amount of iron oxide and an
oxide which dissolved in sulphuric acid. This solution gave^
on evaporation, irregular crystals having a sweetish taste
and forming no alum with potassium sulphate. The sweet
taste suggested for the new element present the name Glu-
cininn, from yXvKvi, sweet. Recently the name Beryllium, "
from the chief source, beryl, has come into more general use.

Occurrence. Beryllium occurs in minerals as follows :
Beryl, Be^l,(SiO,).,

Chrysoberyl, BeAljO^,

Bertrandite, Be,(Be-OH),Si,0„

Phenacite, Be,SiOj,

Leucopkanite, Na(BeF)Ca(SiO,)„

Meliphanite, NaCa,Be,FSi,Ojo

Epididymite, HNaBeSi,0„

Euclase, Be (Al ■ OH)SiO„

Helvite OT danalite, Rj(R,S)(SiOJ„
Gadolinite, FeBe,Y,SijO,„

Trimerite, Be(Mn,Ca,Fe)SiO„

Beryllionite, NaBePO,,

Herderite, Ca(Be(OH,F))PO.,

Hambergite, Be(BeOH)B03,

contains ii-i5%BeO.
19-20%
40-43%
44-46%
io-:2%
10-14%
io-:i%
17-18%

4%

11%

16-17%

19-20%
15-16%

53-54%

13-

BERYLLIUM OR GLUCINUM. 17

Extraction. Beryllium is generally extracted from beryl
by one of the following methods :

(i) The mineral is fused with sodium and potassium
carbonates {vid. Experiment 18).

(2) The finely grotmd mineral is fused .with three times
its weight of potassitmi fluoride. The fused mass is treated
with strong sulphtuic acid and warmed; by this process
the silica is removed as silicon fluoride, and the alumina
and potash are tinited to form the altmi, which may be
crystallized out on evaporation. The beryllium remains
in solution as the sulphate, and may be removed by treat-
ment with ammonium carbonate {vid. Experiments 18
and 20).

(3) The mineral is fused with calcium fluoride. This
process is in general the same as the one indicated in the
second method, except that calcium sulphate is formed
and must be removed (Lebeau, Chem. News lxxiii, 3).

The Element. A, Preparation, Elementary beryllium
may be obtained (i) by bringing together the vapor of
the chloride and soditim in a current of hydrogen (De-
bray, Ann. Chim. Phys. (1855) xliv, 5) ; (2) by fusing the
chloride with potassium (Wohler, Pogg. Annal. xiii, 577);
(3) by heating the chloride in a closed iron crucible with
sodium (Nilson and Pettersson, Ber. Dtsch. chem. Ges. xi,
381, 906); (4) by heating the oxide with magnesium
(Winkler, Ber. Dtsch. chem. Ges. xxiii, 120).

B, Properties, The element beryllium is grayish to
white in color. Unchanged in the air at ordinary tem-
peratures, it bums brightly to the oxide when heated in
air or in oxygen. It does not decompose hot or cold water.
Heated in sulphur vapor it forms the sulphide, and in
chlorine the chloride. It is soluble in dilute and in con-
centrated acids; also in potassium hydroxide with the
liberation of hydrogen. Determinations of its specific
^ gravity range from 1.64 to 2.1.

x8

THE RARER ELEMENTS.

Compounds. A. Typical forms. The following are 1
typical compounds of beryllium;
Oxide, BeO.
Hydroxide, Be(OH),.
Carbonates, BeC03 + 4H,O; arBeCO,-;j'BeO.
Chlorides, BeCl,; BeCl, + 4H,0; a7BeCl,-j'Be(0H), + zH,0.
Chlorate, Be(C10.), + 4H,0.
Bromides, BeBr,; BeBr, + 4HjO.
Iodide, Belj.

Fluorides, BeF,; BeF,-KP; BeF^-aKF.
Nitrates, Be(N0J, + 3H,0; Be(N03),-Be(0H)j + 2H,0;

Be(N03)j-2BeO.
Sulphates. BeSO,; BeS0, + 4H,0; BeSO. + yHp.
Sulphites, BeSO,; BeSO, -BeO; sBeSO.-BeO.
Phosphate, Be,(PO.)5 + 6Hp.
Ferrocyanides, Be,FeC,N,; BejFe(CN),-4Be(0H),.

B. Characteristics. The compoimds of beryllium closely
resemble those of aluminum. The oxide is white, in-
soluble in water, and when freshly precipitated soluble
in excess of potassium hydroxide. If this solution is di-
luted and boiled, the oxide is reprecipitated ; in this reaction
beryllium differs from aluminum. The salts of beryllium,
with the stronger acids (hydrochloric, nitric, and sulphuric)
are soluble, like the corresponding salts of aluminum. The
sulphate of beryllium does not unite with potassium sul-
phate to form an alimi. Ammonium carbonate precipi-
tates the basic' carbonates of both aluminum and beryl-
lium, but the beryllium carbonate is very soluble in excess
and may be reprecipitated by boiling.

Estimation. Beryllium is ordinarily estimated as the
oxide, (BeO), which is obtained by the ignition of the pre-
cipitated hydroxide.

Separation. Beryllium falls into the aluminiun group,
and it closely resembles that element in many reactions.
It may be separated from aluminmn (i) by boiling a dilute

EXPERIMENTAL IVORK ON BERYLLIUM, 19

solution of the two hydroxides in sodium or potassium
hydroxide, berylKum hydroxide being precipitated; (2)
by precipitating the basic acetate of altunintmi, the beryl-
lium salt remaining in solution; and (3) by saturating a
solution of the two chlorides with hydrochloric acid gas
in the presence of ether, the beryllium remaining in solu-
tion, while the aluminum chloride is precipitated (Gooch
and Havens, Amer. Jour. Sci. [4] 11, 416).

EXPERIMENTAL WORK ON BERYLLIUM.

Experiment 18. Extraction of beryllium salts from
beryl (BegAl^Sifi^^. Fuse in a clay crucible 10 grm. of
finely powdered mineral with 20 grm. of a. mixture of sodium
and potassitmi carbonates, and cool. Pour about 20 cm.'
of common sulphuric acid over the fused mass and stir
until it becomes gelatinous. Heat tmtil the excess of sul-
phuric acid is driven off and extract with water. Evapo-
rate to about 100 cm.', filter if necessary, and allow the
potash alum to crystallize out. After removing the alum,
saturate the filtrate with ammonium carbonate in the cold,
allow it to stand for several hours, and filter. Boil the
filtrate and collect the basic beryllium carbonate precipi-
tated (r)t;BeCOg-;vBeO). To purify this salt from iron, dis-
solve it in a small amotmt of acid, add potassium hydroxide
in excess, filter off the ferric hydroxide precipitated, dilute
the filtrate, and boil.

Experiment 19. Precipitation of beryllium hydroxide
(Be (OH) 3). (a) To a solution of a beryllium salt add
ammonium hydroxide, and note the insolubility of the
precipitate in excess of that reagent.

(6) To another portion of the beryllium solution add
a solution of potassium or sodium hydroxide, and note
the solvent action of an excess.

(c) Dilute with water a portion of the alkaline solution

THE RARER ELEMENTS.

obtained in (b) and boil. Note the reprecipitation of the
hydroxide.

{d) To another portion of the alkaline solution ob-
tained in ib) add ammonium chloride, and boil.

(e) To a solution of a beryllium salt add ammonium,
sulphide.

Experiment 20. Precipitation of beryllium carbonate
(a;BeCO,->'BeO). {a) To a solution of a beryllium salt add
sodium or potassium carbonate in solution. Note the
solvent action of an excess and the reprecipitation on
boiling.

(fc) Make a similar experiment, using ammoniimi car-
bonate.

Experiment 2 1 . Precipitation of beryllium phosphate
(Be,(PO,)j). To a solution of a beryllium salt add a solu-
tion of sodium phosphate.

Experiment 22. Precipitation of beryllium ferrocyanide
(Be,Fe(CN)..4Be{0H)J. To a solution of a beryllium salt
add a little potassium ferrocyanide in solution.

Experiment 23. Negative tests of beryllium salts. Try
the action of hydrogen sulphide and ammonium oxalate
upon separate portions of a solution of a beryllium salt.
Add sodium acetate to a solution of a beryllium salt and
boil. Note the absence of precipitation in each case.

YTTRIDM, Y, 89.

Discovery, In the year 1794 Gadolin (Kongl. Vet.
Acad. Handl. xv, 137; Crell Annal. {1796) i, 313) discov-
ered a new earth * in a mineral from Ytterby later called
GadoHnite, which had been discovered by Arrhenius and
described by Geyer in 1788 (Crell Annal. (1788) i, 229).

♦ The term earth is applied to certain metallic oxides which were formerly
regarded aa elementary txKlies, as Y,0), Er,Oj, La,Oj, etc., and names ending
in a jire often used in designating them, as yttria, erhia, etc. The ending
um designates the element, as yttrium, erbium, lantiianum.

YTTRIUM. 2 1

In 1797 Eckeberg confirmed Gadolin's discovery and named
the new earth Yttria (Kong. Vet. Acad. Handl. xviii, 156;
Crell Annal. (1799) 11, 63).

Occurrence^. Yttrium occurs always in combination.
Yttrium earths, chiefly Y^Og, are fovmd as shown in the
following table:

GadoUnite, FeBejYjSijOio 22-46%

III

Yttrialite, R20,-2SiO, 46-47%

Cappelenite, complex silicates 52-53%

Melanocerite, * * * * 9-10%

Caryocerite, * * * * 2- 3%

Tritomite, '' '' 2-3%

II III

Allanite or orthite, HRRjSijOi, o- 4%

Cenosite, H,Ca,(YtEr)2CSi,0i, 37-38%

Thalenite, H^Y.Sip,, 58-63%

Rowlandite, ^YjOj-j/SiOj 61-62%

Bodenite, vid, Allanite 17-18%

Muromonite, * * * * 37-38%

Keilhauite, complex silicates 6- 7%

Tscheffkinite, '* '' 0-3%

Johnstrupite, * * * * i- 2%

Mosandrite, * ' * * o- 3%

Rinkite, '' '' 0-1%

Xenotime, YPO^ 54-64%

Monazite, (Ce,La,Di)P04 o- 5%

Rhabdophanite, RPO.-H^O 2-10%

III

Yttrocerite, 2(2RF,-9CaF,) -aHjO 14-15%

Fluocerite, R,0,-4RF, 3-4%

II III

Samarskite, R3R2(Nb,Ta)P2, 12-16%

III III

Euxmite, R(NbO,),-R,(Ti03)3-|H,0 13-30%

III

Fergusonite, R(Nb,Ta)0^ 30-46%

II III

Yttrotantalite, RRj(Ta,Nb),Oi, -411,0 17-20%

a» _ THE RARER ELEMENTS.

HatchettoHte, R(Nb,Ta),0,-H,0 o- 3%

Annerodite, complex niobate 7~ 8%

Hielmite, complex stanno-tantalate i- 5%

^schynite, R,Nb,0,, ■ R,(Ti,Th)50,, 1-3%

Polyibignite, 5RTiO,-5RZrO,-R(Nb, Ta),0, 3-3%

Po^j'cra.Te, R(NbOj3-2R(TiO.),-3H,0 2{>-3a%

Arrhenite, complex tantalo-niobate 22-23%

Rogersite, " " " 60-61%

Sipylite, complex niobate, Er^O,. . .27%; YjO,, . , 1%

Extraction. The following are common methods for the
extraction of yttrium salts from minerals;

(i) From gadolinite (or any other silicate). The finely
powdered mineral is mixed with common sulphuric acid until
the mass has the consistency of thick paste. It is then
heated imtil dry and hard, pulverized, and extracted with
cold water. From this extraction the oxalates are precipi-
tated by the addition of oxalic acid ; they are then washed,
dried, and heated at 400° C. The oxides thus obtained are
dissolved in sulphuric acid, and the solution is saturated with
potassium or sodiiun sulphate. The double sulphates of
the cerium group are precipitated, and the members of the
yttrium group remain in solution.

(2) From gadolinite. The mineral is decomposed by
aqua regia (vid. Experiment 24).

(3) From samarskite. The mineral is decomposed by
hydrofluoric acid. The niobic and tantalic acids go into
solution, and the yttrium earths, together with uranium
oxide, remain (Lawrence Smith, Amer. Chem. Jour.
V, 44)-

The Element. A . Preparation. Elementary yttrium
may be obtained (i) by heating the chloride with potas-
sium (Berzelius) ; (2) by subjecting the melted double

YTTRIUM. 23

chloride of sodium and yttrium to electrolysis (Cleve, Bull.
Soc. Chim. d. Paris [2] xviii, 193); (3) by heating the
oxide with magnesium (Winkler, Ber. Dtsch. chem. Ges.
XXIII, 787).

B. Properties. Yttrium is a grayish-black powder,
which decomposes water only slightly at ordinary tempera-
tures, but more rapidly on boiling, forming the oxide.
Ignited on platintun in the air, it bums to the oxide with a
brilliant light; in oxygen with a very intense glow. It is
very soluble in dilute acids, including acetic, but is only
slightly soluble in concentrated sulphuric acid. It decom-
poses potassivun hydroxide at the boiling temperature.

Compounds. A. Typical forms. The following are typ-
ical compounds of yttrium:

Oxide, Y,0,.
Hydroxide, Y(OH),.

Carbonates, Y,(CO,), + 3H,0 ; Y,(CO,), • Na,CO, + 4HP ;
Y,(C0,),-(NH,),C03 + 2H,0.

Chlorides, YCl,; YClj + eHjO; YCl,-3HgCl, + 9H,0;
YCI3 • 2AuCl,-|- i6H,0 ; 2YC1,- 3l>tCl,-|- 24II ,( ).

Chlorate, Y(C10,), + 8HjO.
Perchlorate, Y(C10,), + SH^O.
Bromides, YBr,; YBr, + 9H,0.
Bromate, Y(BrO,), + 9HjO.
Iodide, YIj.

lodate, Y(I0,),-|-3H,0.
Periodate, Y,0, • 1,0, + 8H,0.

Fluoride, YF,-|-o.5H,0.

Nitrates, Y(NO,), + 6H,0 ; 2 Y,0, • 3N,0, + 9H,0.

Cyanides, YKFe(CN),-|-2H,0; Y(SCN),-|-6H,0.

Sulphates, Y,(SO,), + 8H,0 ; Y, (SO,), -41^,80,;

Y,(S0,),-Na,C0,-|-2H,0.
Sulphite, Y,(S0,),-|-3H,0.

'A THE RARER ELEMENTS.

Seleniates, Y,(SeO,), + 8H,0 ; Y,(SeO,), ■ K,SeO, + 6H,0 ;

Y,(SeO,), ■ (NH,),SeO, + 6H,0.
Selenites, Y,(SeO,}, + i2H,0; Y,0,-4SeOj + 4H,0.
Sulphide, Y,S,.
Oxalate, Y,(C,0,), + gH,0.
Phosphates. YPO.; Y(PO,),; YHPjO, + 3-5H,0.
Chromate, Y/CrO,),-K,CrO,+a;H,0.
Tungstate. Y,(W0J, + 6H,0.
Carbide, YC,.

B. Characteristics. The compounds of yttrium have '
few characteristic reactions. They resemble quite closely
the compounds of aluminum, but yttrium differs from
aluminum in having a hydroxide insoluble in excess of
sodium or potassium hydroxide and in forming no alums.
The salts of yttrium give no absorption spectra. Yttrium
sulphate differs from the sulphate of cerium in forming
no insoluble double sulphate with potassium or sodium
sulphate.

Estimation, Yttrium is generally weighed as the oxide,
(YjOj), which has been obtained by the ignition of the
hydroxide or the oxalate.

Separation. In the course of analysis the yttrium
earths are precipitated with the aluminum group. They
may be separated from aluminum by precipitation with
oxaHc acid or ammonium oxalate in faintly acid solution;
in this reaction they resemble the other members of the
rare-earth group (Ce, La, Di, Th, Zr, etc.). They may be
separated from these by saturating a solution of the sul-
phates with potassium sulphate ; the yttrium earths do
not form a double sulphate insoluble in potassium sulphate
as do the others.

For the separation of yttrium from the very rare mem-
bers of its group (Yb, Er, Tr, etc.), vid. Dennis and Dales,
Jour. Amer. Chem. Soc. xxiv, 401.

r

EXPERIMENTAL IVORK ON YTTRIUM. 2$

EXPERIMENTAL WORK ON YTTRIUM.

Experiment 24. Extraction of yttrium salts from gado-
Unite (BejFeYjSijOj^. Warm 5 grm. of finely powdered
mineral with aqua regia until it is completely decomposed.
Evaporate on a water-bath and desiccate to remove the
silica. Extract with hot water and a little hydrochloric
acid, and add to the extract ammonium oxalate vintil
precipitation ceases. Filter off the precipitate, which con-
sists of the oxalates of the yttrium and cerium groups, to-
gether with traces of the oxalates of manganese and cal-
cium; dry and ignite. Dissolve in a small amovint of
hydrochloric acid the oxides thus obtained, and saturate
the solution with potassium sulphate; this precipitates
the members of the cerium group as the double sulphates.
Filter, and wash with a solution of potassium sulphate.
From the filtrate precipitate the yttrium earths by an
alkali hydroxide or oxalate. To remove the manganese
and calcium, dissolve the precipitate in nitric acid, evapo-
rate to dryness, and heat tmtil the manganese salt is decom-
posed. Extract with watei*, filter off the oxide of man-
ganese, treat the filtrate with ammonitim hydroxide, and
stir thoroughly. The calcium hydroxide will be dissolved,
and the yttrium earths precipitated.

Experiment 25. Precipitation of yttrium hydroxide
(Y(0H)3). (a) To a solution of an yttritim salt add am-
monium hydroxide.

(6) Repeat the experiment, using sodium or potassium
hydroxide.

Note the insolubility in excess in each case.

{c) Precipitate yttritim hydroxide by the action of
ammonium sulphide.

Experiment 26. Precipitation of yttrium carbonate
(Yj (003)3). (a) To a solution of an jrttrium salt add
ammonium carbonate.

THE R/IRER ELEMENTS.

(b) Repeat the experiment, using sodium or potassium

carbonate.

Note the solubility in the cold upon the addition of a
excess of the alkali carbonates, and the reprecipitatio
on boiling,

(c) Try the action of the common acids upon yttriuiB
carbonate.

Experiment 2 7. ' Precipitation of yttrium oxalaU
(Yj{CjO^)3). To a solution of an yttrium salt add a solu-^
tion of either oxalic acid or an alkali oxalate.

Experiment 28. Precipitation of yttrium phosphatesM
CY,(HPO,),; YPO,). To a solution of an yttrium salt!
add sodium phosphate in solution (NajHPO^). The pre-J^
cipitate is said to be of the acid form Yj(HPOJ,. Thej
neutral phosphate (YPO,) is formed by treating an yttriu:
salt in solution with an ammoniacal phosphate.

Experiment 29. Precipitation of yttrium ferrocyania
(YKFe(CN)„). To a solution of an yttrium salt add potas-
sium ferrocyanide.

Experiment 30. Precipitation of yttrium chromaU
{a;Yg(CrO,)j->'YjOj). To a solution of an yttrium salt ad(i
a solution ofpotassium chroma te, and neutralize if necessaryj

Experiment 31, Precipitation of yttrium fluoride (YF,)
To a solution of an yttrium salt add potassium fluorida.^

Experiment 32, Negative tests of yttrium salts. Not<
that hydrogen sulphide gives no precipitate with yttriuj
salts, and that saturation of a solution of an yttrium saltB
with potassium or sodium sulphate gives no insoluble 1
double salt.

THE GAD0LI5ITE OR YTTRTOM EARTHS

OTHER THAN YTTRIA,

Associated with yttria, and resembling it in many!
reactions, are several very rare earths which, together withl
yttria, comprise the group called the Gadolinite or Yttrium I

THE GADOLINITE OR YTTRIUM EARTHS. 27

Earths. The metak of these very rare oxides are the
following :

I. II.

Terbium, Tr, 16 1-3 Samarium, Sm, 150

Erbium, Er, 166 Decipium, Dp, 171

Holmium, Ho, 162 Gadolinium, Gd, 156

Thulitmi, Tm, 171

Dysprosium, Dy.

Ytterbium, Yb, 1 73

Philippium, Pp, 123-6

Scandium, Sc, 44 . i

The elements in column II are classed by some authori-
ties with the cerium group.

Discovery.* In 1843 Mosander (J. pr. Chem. xxx, 288)
annotmced, as the result of his investigation of yttria, its
separation into three earths, two white and one yellow.
To 'the less basic of the white oxides he gave the name
Terbitmi earth, to the more basic the original name Yttrium
earth, and the yellow oxide he called Erbitim earth.

In 1878 Marignac (Compt. rend, lxxxvii, 578) fovind in
gadolinite the oxide of a new element which he named Ytter-
bium, and the same year Delafontaine (Compt. rend, lxxxvii,
559, 632) annotmced the isolation from a North Carolina
samarsldte of the earths of Decipitmi and Philippium.

The following year Nilson (Ber. Dtsch. chem. Ges. xii,
554), while engaged in extracting ytterbitmi from euxenite,
separated an earth of much lower atomic weight, the
unknown element of which he called Scandium. Another
earth isolated in 1879 is the oxide of Samarium, discovered
by Lecoq de Boisbaudran (Compt. rend, lxxxviii, 323)
in the cotirse of an examination of the absorption spectra
of the earths separated from samarskite.

In 1880 Cleve (Compt. rend, lxxxix, 478), while work-

* For a recent and more detailed account of the discovery of these
earths t^. Baskerville. Science, New Series, xvn, 774.

38

THE RARER ELEMENTS.

ing on erbium earth, discovered two elements, Holmium
and Thulium, which he separated as the oxides.

Six years later Marignac and Lecoq de Boisbaudran
(Compt. rend, cii, 902), during the study of terbium earth,
separated the oxide of an unknown element named by
them Gadolinium, and in the same year Lecoq de Bois-
baudran (Compt. rend, cii, 1004) made the further an-
nouncement of the isolation of a new earth from the oxide
of holmium, that of Dysprosium.

Occuireoce. These earths are found associated with
yttrium in small quantities and varying proportions {vid.
Occurrence of Yttrium).

Extraction.* Methods for the extraction of the yttrium
earths have already been given {vid. Extraction of Yttrium),
Methods for their separation are as follows;

(1) Fractional precipitation by ammonium hydroxide
(Mosander) ;

(2) Fractional precipitation by potassium oxalate
(Delafontaine) ;

H (3) Successive ignitions of the nitrates, and extractions

^ft with water {Bahr and Bunsen);

^B (4) Precipitation by means of lactic acid (Waage) ;

H (S) Treatment with ethylsulphate (Urbain).

H The Elements. The metallic elements of these earths

^1 have not been isolated.

^1 Compounds. A . Typical forms. The typical com-

^P pounds of five elements of the yttrium group are given on

H the next page.

^m B. Characteristics.. The existence of the earths of er-

^1 bium, terbium, ytterbium, scandium, and samarium has

I

V

References: Mosander and Delafontaine, J. pr. Chem. xciv, 297; Eahr
and Bunsen, Ann. Chem. Pharm. cxxxvii, i ; Auer v. Welsbach, Monatshefte f.
630; Waage, Chem. Ztg. (1895), 1072; Drossbach, Ber. Dtsch. chem.
[, 2452; Urbain, Chem. Ztg. {1S98), 271; Dennis and Dales, Jour,
Amer. Chem. Soc. xxiv, 401.

THE G^DOUNITE OR YTTRIUM EARTHS.

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THE RARER ELEMENTS.

been quite definitely established. The other members of
the gadolinite group are still more or less in doubt. Of the
five mentioned above, the first four closely resemble yttrium.
Solutions of terbium, ytterbium, and scandium salts give
no absorption spectra. The salts of erbium are of a rosy
tint, and give an absorption spectrum. The double sul- i
phates of these io\iT elements respectively with potassium i
sulphate are soluble in a solution of potassium sulphate,
the ytterbium and scandium salts being more soluble, how-
ever, than those of erbium and terbiimi. Samarium re-
sembles cerium. Its salts are yellowish, and the solutions
give an absorption spectrum. The double sulphate with
potassium sulphate is insoluble in a solution of potassium
sulphate.

CERIUM, Ce, 140.

Discovery. In the course of the analysis of a mineral
from Riddarhyttan, Sweden, in 1803, Klaproth discovered
an earth which, while resembling yttria in many of its
reactions, differed from it in being insoluble in carbonate
of ammonium, and in acquiring, when ignited, a light brown
color. Because of this latter peculiarity, the name Ochroite
suggested itself to him, from 'atXpoi, yellow brown (Phil.
Mag. XIX, 9S). At the same time, and independently of
Klaproth, Berzelius and Hisinger made the same discovery.
Their name for the new element was Cerium, chosen in honor
of the discovery of the planet Ceres by Piazzi in 1801 (Phil.
Mag. XX, 155; XXII, 193).

Occurrence. Cerium is found in many minerals, asso-
ciated, usually, with lanthanum and didymium.

Contains
Ce,0. Di,0,+ lA,O,

Ceriie, (Ca.Fe) (CeO) (Ce, ■ 3OH) (SiOJ,, . 24-65 % 7-35%

Allanite or orthite, HRR^Sip,, 1-18% 1-16%

Gadolinite, Be,FeY,Si,0,o 1-10% 2-20%

CERIUM. 3^

Contains
Ce,0, Di,0,+La,0|

Cappelenite, complex silicates 1-2% 2-3%

Melancx^erite, * * * * 20-21 % 20-21 %

Caryocerite, ** ** 14-15% 20-21%

Tritomite, ** ** 19-21% 21-26%

Tscheff kinite, * * silico-titanates ..12-20% 1 7-20 %

Johnstrupite, ** ** ** 12-13% *

kosandrite, '* '* '' 16-26% *

Rinkite, '* '' '' 21-22% *
Mackintoshite,

UO, . 3Th03 . 3Si03 . 3H,0 .... 4S-46%t

Monazite, (Ce, La, Di)PO^ 16-36% 20-24%

Churchite, R3P,03.4H30 50-51%

Xenotime, YPO, 0-11% *

Rhabdophanite, RPO, -H^O 23% 55%

Fluocerite, R^O, .4RF3 39-46% 30-36%

Tysonite, (Ce, La, Di)F, 40% 30%

III

Yttrocerite, (2RF, • gCaF,) • 3HP 5 % 5 %

Parisite, (CaF) (CeF)Ce(CO,) 38 % i S %

(Ce, La, Di),C,0,- (Ce, La, Di)F, . . 28-41 % 35-46%

Lanthanite, Laj(COj)j-9HjO 52%

II III

Samarskite, R,R,(Nb,Ta),0„ 2-5% *

Fergusonite, R(Nb,Ta)0, 0-9% *

in III

Euxenite, R(NbO,),-R,(Ti03),-|H,0. 2- 8%

ZirkeUte, (Ca,Fe)0 • 2(Zr, Ti, Th)Oj. . . 2-3%

IIJ Til

Polycrase,R(NbO,),-2R(TiO,),-3H,0 2-3%
Polymignite,

5RTiO,-5RZrO,.R(Nb,Ta),0,.... 6% 5%

III III

■ ^schynite, R,Nb,0.,-R,(Ti,Th),0„.- 18% 5%

• Included under Ce,0,. t Ce,0,+ ThO,.

3* THE RARER ELEMENTS.

Contains
Ce,Qi DiaO,+La,Ob

Hielmite, formula doubtful 0.5- i %

o

Annerodite, * * * * • 2-3%

II III

Yttrotantalite, RR3(Ta,Nb),Oi5 -41130. 0-2%

Sipylite, complex niobate 1% 8%

Pyrochlore, RNb,0e.R(Ti,Th)03 5-7%

Arrhenite, formtila doubtful 2- 3% *

Extraction. Cerium is generally extracted from cerite
through decomposition of the mineral by heating it with
strong sulphuric acid {vid. Experiment 33). The decom-
position may be accomplished also by the action of a mix-
ture of strong hydrochloric and nitric acids, but better
results may be expected by the former method.

The Element. A, Preparation, Elementary ceritim may
be obtained (i) by reducing the chloride with soditim or
potassium (Mosander) ; (2) by subjecting the double chloride
of cerium and sodium to electrolysis (Pogg. Annal. clv, 633).

B, Properties, In appearance ceritim resembles iron.
While fairly stable in dry air, it oxidizes quickly in moist air. *
It takes fire more easily than magnesitun, and melts at a
lower temperature than silver and at a higher temperature
than antimony. It is soluble in dilute acids, but is not
attacked by concentrated sulphuric or nitric acid. It com-
bines with chlorine, bromine, and iodine, forming salts. Its
specific gravity is 6.6.

Compounds. A, Typical forms. The following are typ-
ical forms of the two classes of cerium compoimds:

Oxides CcjOj CeO,

Hydroxides Ce20,.6H20 2Ce02.3H20

Carbonates Ce2(CO,)8+ sHjO Ce(C0,)2+ o.sHjO

Chloride CeClj

Bromide CeBfj

Iodide Celj

Perchlorate Ce(C104)8-f8H20

* Included under CcjOj.

CERIUM. 33

Bromatc Ce(BrOJ,+ 9HjO

lodate Ce(IOj),+ 2H,0 ^ .

Fluorides CeF, CeF4+ H,0

Cyanide Ce(CN),

Ferroc3ramdes. . . Ce4(FeC^NJ,+ 3oHjO

CeKFeC,N,+ 3H2O

Ferricyanide CeFeC,N,+ 8HjO

Sulphocyanide . . Ce(CSN),+ yHjO

Sulphide C^

Sulphite Ce,(SO,),+ 3H,0

Sulphates. Ce,(S04),+ 3. 5. 6, 8, 9, and CeCSOJ, + 4H,0

Double sulphates. CejCSO^), • 3K^04+ 2H,0 CeCSOJ, • 2KJSO4+ 2H,0

CeaCSOJ, . 3Na,S04+ 2H,0

Ce^CSOJ, . (NH J2SO4+ 8H,0

Nitrates :Ce(NO,)3+6H,0 Ce(N0,)4

Double nitrates. .CejCNOj),- 3Zn(N03)j+ 2Ce(N03)4.4KNO,+ 3H2O

24H2O

Ce,(NO,),.3Co(NO,),+ 2Ce(NO,)4.4(NHJNO,+

24H2O, etc. 3H2O

Phosphates CePO^ (CeOj)^. (P205),+ 26H,0

Oxalate CejCCjOJs

Carbide CeC,

B. Characteristics, Cerium exists in compounds in two
conditions of oxidation. The higher or eerie salts are
easily reduced to the lower or cerous condition by the
ordinary reducing agents (e.g. HjS, SOj, H^CjO^, etc.),
and the cerous salts may be oxidized to the eerie condition
by oxidizing agents (e.g. Pb02 + HN0g, H2O2, KMnO^, etc.).
In general the cerous salts are colorless, and the eerie yellow.
The lower oxide of cerium, (CcjOg), on ignition goes over to
the higher condition, (CeOj). The cerous salts are the more
stable, and consequently they form the greater number.
They resemble the yttrium salts in many of their reactions,
and are distinguishable from them chiefly by the formation
of the double sulphates with soditim sulphate and potas-
sium sulphate respectively, by the comparative insolubility
of the carbonate in ammonium carbonate, and by the possi-
bility of oxidation to a higher condition. Solutions of pure
cerium salts give no absorption spectra.

34 THE RARER ELEMENTS.

Estimation. A. Gravimetric , Cerium is us\ially deter-
mined gravimetrically as the dioxide, (CeOj), obtained by
the ignition of the hydroxide or the oxalate.

B, Volumetric, (i) When eerie oxide, (CeO 2), is treated
with hydrochloric acid in the presence of potassiuni
iodide, iodine is set free, according to the following
eqtiation :

2Ce02 + 8HCl + 2KI=2CeCl3 + 4H,0 + 2KCl+I,.

The iodine may be estimated in acid solution by stand-
ard thiosulphate, or in alkaline solution by standard
arsenious acid (Bimsen, Ann. Chem. Pharm. cv, 49 ; Brown-
ing, Amer. Jour. Sci. [4] viii, 451).

(2) When ceritun oxalate is dissolved in sulphuric acid
the oxalic acid may be readily determined by potassium
permanganate > and the amount of cerium present may
be thus estimated (Stolba, Zeitsch. anal. Chem. xix, 194;
Browning, Amer. Jour. Sci. [4] viii, 457).

(3) When yellow eerie compotmds are treated with
hydrogen dioxide in acid solution, they are reduced to
cerous compounds, witK>bleaching of color (Knorre, Zeitsch.
angew. Chem. (1897), 685):

2Ce(S0,), + H,0, = Ce,(S0,)3 + H,SO, + O,.

Separation. Cerium falls into the analytical group
with aluminum, iron, etc. Together with the other rare
earths it may be separated from these by oxalic acid or
oxalate of ammonium. For separation from the yttrium
earths, vid. page 24.

Cerium may be separated from lanthanum and didy-
mium * by the following methods: (i) by treating the hy-
droxides suspended in a solution of ' caustic potash with
_ ■ «•■ — .

* For an instructive review of the methods for the separation of cerium,
lanthanum, and didymium, see P. Mengel, Zeitsch. anorg. Chem. xix

(1899), 67.

CERIUM. 35

chlorine gas, as in Experiment 33 (Mosander, J. pr. Chem.
XXX, 267) ; (2) by treating a neutral solution of the cerium
earths with an excess of a hypochlorite and boiling, thus
precipitating eerie oxide (Popp, Ann. Chem. Pharm. cxxxi,
359) ■» (3) hy treating a solution of the cerium earths with
soditmi peroxide, in place of the hypochlorite in (2) (O. N.
Witt, Chem. Ind. (1896), 11, 19); (4) by treating the oxa-
lates of the ceritmi earths with warm dilute nitric acid,
thus separating the ceritmi as basic nitrate (Auer von
Welsbach, Monatshefte f. Chem. v, 508); (5) by treating
a solution of the salts with hydrogen dioxide in the presence
of magnesium acetate (Meyer and Koss, Ber. Dtsch. chem.
Ges. XXXV, 672).

From thorium cerium may be separated (i) by repeated
precipitations on boiling with sodium thiosulphate (Fre-
senius and Hintz, Zeitsch. anal. Chem. xxxv, 543) ; (2) by
boiling with potassitmi nitride (Dennis and KortrighSt,
Amer. Chem. Jour, xvi, 79):

Th(N03), + 4KN3 + 4H,0 = Th(OH), + 4KNO3 + 4HN3 ;

(3) hy boiling a neariy neutral solution of the chlorides
with copper and cuprous oxide (Lecoq de Boisbaudran,
Compt. rend, xcix, 525) ; (4) by the action of fumaric acid
in 40% alcohol upon solutions of the salts in 40% alcohol
(Metzger, Jour. Amer. Chem. Soc. xxiv, 901). In all of
these methods the thorium is precipitated.

Cerium is separated from zirconium by fusion of the
oxides with acid potassium fluoride, and extraction with
water and a little hydrofluoric acid; the potassium fluo-
zirconate is dissolved, and the thorium and ceritmi remain *
(Delafontaine, Chem. News lxxv, 230).

Experimental Work. Vid, Lanthanum and Didymium.

* For the action of organic bases as precipitants of the rare earths, vid.
Jefferson, Jour. Amer. Chem. Soc. xxiv, 540; Baskerville, Science, New
Series, xvi, 215; Kolb, J. pr. Chem. [2] i^xvi, 59; Allen, Jour. Amer. Chem.
Soc. XXV, 42 X.

3^ THE RARER ELEMENTS.

[, La, 138.77; DIDYMIXTH, Di, 142.3.
(Praseodymium, Pr, 140.5; Neodymium, Nd, 143.6.)

Discovery. In 1839 Mosander found that when the
nitrate of cerium had been ignited, he was able to extract
from it by very dilute acid an earth which differed in prop-
erties from that of cerium, while from the portion remain-
ing imdissolved he obtained the reactions of the cerium
earth. He supposed the unknown substance of the newly
discovered earth to be an element, and named it Lan-
thantmi, from Xavddyeiv, to hide (Pogg. Annal. xlvi, 648;
.Liebig, Annal. xxxii, 235).

In 1 84 1, while engaged in further work upon the extrac-
tion of mixtures of ceriimi and lanthanimi oxides by dilute
nitric acid, he succeeded in separating from the lanthanum
oxide another earth, rosy in color, going over to dark brown
on being heated. Reserving for the residual oxide the
original name Lanthanum earth, he called the base of the
new oxide Didymiimi, from Sidvpios^ twin, — a name sug-
gested by its close relationship to lanthanimi and its
almost invariable occurrence with it (Pogg. Annal. lvi, 503).

I1U1885 Auer von Welsbach annoimced that by long-
continued fractional crystallization of the double nitrates
of ammonium with lanthanum and didymium in the pres-
ence of strong nitric acid, he had separated didymitun
into two elements (Sitzungsber. d. k. Acad. d. Wiss. (1885)
xcii. Heft I, II, 317; Ber. Dtsch. chem. Ges. xviii, 605).
The lanthanimi crystallized out first, and afterward the
decomposition of the didymium took place. To these
new elements he gave the names Praseodymitim (7rpd<rtvos,
leek-green) and Neodymium (veos*, new).

In 1888 Krtiss and Nilson stated, as the result of their
work on the absorption spectrum of didymitim, that they

LANTHANUM; DIDYMIUM. 37

had discovered indications of the presence of no less than
eight elements (Ber. Dtschi. chem. Ges. xx, 2134, 3067).
These results, however, have not as yet been fully con-
firmed. At the present time the existence of praseodym-
ium and neodjrmium is generally accepted.

(Though the term '*didymitmi" does not designate
an element, it is still in general use, and fqr the sake of
convenience it is employed in the following pages. While
there is a considerable body of information concerning
didymitmi, its constituent elements have not yet been
so fully studied, — perhaps because of the long and tedious
operation involved in their separation. For that reason,
at all events, no experimental work on them is given in
this book.)

Occurrence. Lanthantmi and didymium are found al-
most invariably associated with cerium {vid. Occurrence
of Cerium).

Extraction. In the process of extracting cerium from
cerite {vid. Experiment 33), the oxalates of cerium, lan-
thanum, and didymium are precipitated together. Lan-
thanum and didymium must next be separated from
ceritmi, and then from each other. Afterward didymitun
may be decomposed into its two constituents. Several
methods of accomplishing these three steps are indicated
under Separation of Cerium, and of Lanthanum and Didy-
mitun.

The Elements. I. Lanthanum. A, Preparation, The
element lanthanum may be obtained (i) by reducing
the chloride with potassium; (2) by subjecting the double
chloride of lanthanum and sodium to electrolysis.

B. Properties. Lanthanum is a metallic element of a
lead-gray color. It decomposes cold water slowly and hot
water more rapidly, with the evolution of hydrogen. It
oxidizes easily in the air. Its specific gravity is from 6.04
to 6.19.

38

THE RARER ELEMENTS,

II. DiDYMiuM. Elementary praseo- and neodymiunl
have not been isolated.

A, Preparation. Didymium may be prepared from the
salts by the methods indicated for lanthanum {vid. Prep-
aration of Lanthanum).

B. Properties. Metallic didymium is yellowish white.
It decomposes cold water slowly and oxidizes in the air.
Its specific gravity is 6.54.

Compotinds. A, Typical forms. The following are t3rp*»
ical compotmds of lanthantim and didymium:

Oxides La,0, Di20,

Di,0»

Hydroxides La(OH), Di(OH),

Chlorides LaCl,+ yHjO DiCl,+ 6H,0

Oxyclilorides La(OClj) Di(OCl),

Chlorate La(C108)8

Perchlorates. .... 1^(01008+ 9HjO Di(C104),+ 9H,0

Bromides. .' LaBrjH- yHjG DiBr8+ 6H2O

Bromates La(Br08)8+ qHjG DiCBrO,),^- 9H,0

lodates La2(IO,),+ aHjG Di(I0,)8+ eilfi

Periodates La(I04)8+ 2H,0 Di(IO08+ 4HjO

DiO(IOJ+4H80

Sulphites La,(S08),+ 4HjO Di2(S08)8+ 6H80

Sulphates 1^2(804)8+ qHjO Dij(S04)8+ SHjO

Double sulphates. 1^2(804)8 • 3K2SO4 1)12(804)8 • 3K2SO4

I^a2(S04)8 • Na2S04+ 2H2O 1^2(804)8 • Na2S04+ 2H2O
I.a2(S04)8 • (NH4)2S04+ 8H2O Di2(S04)8 • (NH4)2S04+ 8H,0

Dithionates . 1^2(320,),+ 16H2O Di2(S208)8+24H20

Selenites La2(SeO,)8+ 9H2O Di2(Se08)8+ 6H2O

Seleniates La2(Se04)8+ 6H2O Di2(Se04)8+ 8H2O

Double seleniates.La,(Se04)8 • K2Se04+ 9H2O Di2(Se04)8 • K2Se04

La2(SeO J8 • Na2Se04-f 4H2O Di2(Se04), . Na2Se04
La2(Se04)3 • (NH4)2Se04+ Di2(Se04)8 • {^VL^^^O^
9H2O

Nitrates La(N08),-f 6H2O Di(N08)8+6H20

Phosphates LaP04; also meta and pyro DiP04+H20; also meta and

forms pyro forms

Arseniates l^Q.^^JL^^^di J>i2^ii^'^0^t

Arsenites La2H8(As08)8 Di2H8(As08)8

Carbonates LajCCOJj-f 3H2O r>i2(C08)8+ 6H2O ; also double

salts with K, Na, and NH^
carbonates

LANTHANUM; DIDYMIUM. 39

Oxalates La^CCjOJ, Di,(CjO^>,+ i2HjO

Chromates LajCCrOJ, I^ijCCrOJiH- 7H,0

Molybdates LaHjCMoOJ, DiHjCMoOJ,

Tungstates LajCWOJ, DiCWOJ,

Sulphides. La^ Di^

The following compounds of praseo- and neodymium
have been described :

Oxides PfjO, NdjO,

PrA NdjO^?

PrA? NdA?

Carbonate Prj(C08),+ 8H,0

Chlorides PrCl,+ 7H,0 NdCla+ 6HjO

Bromide PrBr,+ 6H2O

Sulphates Pra(S04)3+ 8H,0 Nd^CSO^jH- 8H,0

PrjOjSO^ NdjOjSO*

PrH,(S04), NdH,(SOJ,

Double sulphates. PrjCSOJ, • 3K2SO4+ HjO

PraCSOJ, . (NH J,S04+ SH^O

Sulphides Pr^Sj NdjS,

Selenite Pr3(Se03),.HaSeO,+ 3HjO

Seleniate Pr2(Se04)8+ SHjO

Double seleniate. Pr2(SeOj3.K2Se04+4H20

Nitrates Pr(N03)s+ 6H2O Nd(NOJ,

Double nitrates. . PrCNOj), • 2(NHJN0j+ 4H2O

Pr(N0s)5.2NaN08+H20
Double cyanide. . 2Pr(CN)8- Pt(CN)24- iSHjO
Oxalate Pr2(C204)3+ loHjO

B, Characteristics. The compounds of lanthanum, di-
dymium, and cerium in the cerous condition are very
similar in their behavior toward chemical reagents. The
compounds of lanthanum and didymium may be distin-
guished from those of cerium by the absence of yellow color
on the addition of oxidizing agents, — a color character-
istic of the higher oxide of cerium. Lanthanum may be
distinguished from didymium by the colorlessness of its
salts and by the absence of an absorption spectrum. Di-
dymium salts in general are of a rosy color and give a
distinctive absorption spectrum.

40

r«e, RARER ELEMENTS.

The compounds of praseo- and neodymium have not
been sufficiently studied to allow any detailed description
of their characteristics to be given. Neodymium salts
are rose-colored and are very similar in appearance and
in behavior to the salts of the original didymium. The
oxide NdjOj is bluish. Praseodymium salts are green.
While their chemical form resembles closely the form of
the neodymi\un salts, higher oxides are definitely known
in the case of praseodymium. The ordinary oxide Pr^Og
is greenish white ; the higher oxide Prp, is nearly black.
Each of the two elements has distinctive spectra, spark
and absorption. Mixed, the elements give the didymium
spectrum.

Estimation. Like cerium, lanthanum and didymium
are generally estimated as oxides, obtained by ignitio)
of the hydroxides or oxalates.

Separation. A. Lanltianum from didymium. Lanth;
num may be separated from didymium (i) by dissolv*3
ing the sulphates in water at 9° C. and gradually raisin^-fl
the temperature, — the lanthanum sulphate separating '
first (Hermann, J. pr. Chem, lxxxii, 385); (2) by heating
the nitrates at 4oo°-5oo'' C. and extracting with water, —
the didymium tending to form an insoluble basic nitrate
(Damour and Deville, Bull. See. Chim. d. Paris 11, 339);
(3) by dissolving half of a given amoimt of the oxides in
warm dilute nitric acid, then adding the other half, witi
constant stirring, cooling the mass, and extracting witM
water (vid. Experiment 33). The didymium will be found
in the residue (Auer von Welsbach, Monatshefte f. Chei
V, 508).

B. Praseodymium from neodymium. Didymium nta^
be separated into its two constituents (i) by making seven
hundred fractional crystallizations, first of the doublfl
nitrate of ammonium and didymium and later of Xhi
double nitrate of sodixun and didymium,- in the presence c

EXPERIMENT/IL IVORK ON CERIUM, LANTHANUM, ETC. 41

nitric acid, — ^the neodymium salt being the more soluble
(Auer von Welsbach, Sitzungsber. d. k. Acad. d. Wiss.
(1885) xcii, Heft I, II, 317; (2) by allowing nitric acid
to act upon the oxalates, — the praseodymium salt being
the more soluble (Scheele, Ber. Dtsch. chem. Ges. xxxii,
417) ; (3) by treating the sulphates with water, — the praseo-
dymium sulphate being the more soluble (Muthmann and
Rolig, Ber. Dtsch. chem. Ges. xxxi, 1718); (4) by making
fractional precipitations of a solution of didymium nitrate
by means of sodium acetate and hydrogen peroxide, —
the praseodymium separating first (Meyer and Koss, Ber.
Dtsch. chem. Ges. xxxv, 676); (5) by saturating a cold
concentrated solution of citric acid with the hydroxides
free from ammonia and excess of water, then filtering
and heating, — the green citrate of praseodymium being
precipitated, insoluble in hot water (Baskerville, Science,
New Series, xvi, 214).

EXPERIMENTAL WORK ON CERIUM, LANTHA-
NUM, AND DIDYMIUM.

Experiment 33. Extraction of cerium, lanthanum, and
didymium salts from cerite (Ca,Fe)(CeO)(Ce2 -3011) (8103)3.
Treat 25 grm. of finely powdered cerite with common
sulphuric acid and stir tmtil the mass has the con-
sistency of thick paste. Heat until the excess of sul-
phuric acid is removed and then keep the mass for
some time at low redness. Cool, pulverize, and digest
with cold water tmtil no further precipitate appears upon
the addition of ammonium oxalate to a few drops of the
extract. Pass hydrogen sulphide into the solution to
remove traces of bismuth and copper. Filter, and to the
filtrate add oxalic acid to complete precipitation of the
oxalates of cerium, lanthanum, and didymitun. Ignite the
oxalates, and dissolve in hydrochloric acid the oxides
obtained. To this solution add potassium hydroxide

4* THE RARER ELEMENTS.

until the precipitation of the hydroxides is complete.
Make up the volume of the liquid in which the hydroxides
are suspended to about 200 cm.* Add about 5 grm. of
potassitmi hydroxide to insure an excess, and pass a slow
current of chlorine gas through, stirring from time to time,
until the liquid is no longer alkaline in reaction and the
precipitate has assumed a deep-yellow color. By this
process the cerium hydroxide is oxidized to the dioxide,
which remains imdissdlved, and the lanthanum and didy-
mium hydroxides are dissolved. When the separation is
complete, a portion of the washed precipitate dissolved in
hydrochloric acid should give no evidence of the presence
of didymium, — for example, no absorption spectrum {vid.
Experiment 43). The absence of didymitim at this point
is considered sufficient evidence of the absence of lanthanum.
To the solution containing the lanthantmi and didymium,
the cerium dioxide having been removed by filtration, add
oxalic acid until the precipitation is complete. Filter
off the oxalates, wash, dry, and ignite. Dissolve one half
of the oxides obtained by this process in the least possible
amoimt of warm, dilute nitric acid, and add the remainder
of the oxides to the solution. Stir thoroughly, and when
the mass is cool extract with water. The didymium tends
to be in the residue and the lanthanum in solution.

Experiment 34. Reduction and oxidation of cerium
compounds, (a) To a small portion of the carefully washed
cerium dioxide obtained in the previous experiment add
a little hydrochloric acid diluted with an equal volume
of water and boil. Note the evolution of chlorine and
the ultimate colorless solution of cerium chloride, (CeClg).

(6) To a portion of the solution obtained in (a) add
a few drops of ammonium hydroxide in excess and some
hydrogen dioxide. Note the orange-yellow precipitate
(CeOg?). Other oxidizing agents, such as sodium hypo
chlorite, sodium peroxide, lead dioxide, potassium per-

EXPERIMENTAL ^ORK ON CERIUM, L4NTHj4NUM, ETC. 43

manganate, etc., may be used. Boil the solution holding
the precipitate in suspension and note that the deep-yellow
color changes to a lighter yellow. The precipitate becomes
essentially the dioxide, (CeOj).

(c) To another portion of the washed cerium dioxide
from Experiment 33 (2Ce02 -31120) add hydrochloric acid
as before, and also acrylstal of potassium iodide in the
cold. Note the liberation of iodine according to the
reaction 2Ce02 + 8HCl+2KI = 2CeCl3 + 2KCl + l2 + 4Hp.

Experiment 35. Precipitation of cerous hydroxide,
(CeCOH),). (a) To a solution of cerium chloride add
sodium, potassium, or ammonium hydroxide in solution.
Note the insolubility of the hydroxide in excess of these
reagents.

(6) Repeat the experiment with tartaric acid present
in the solution.

Experiment 36. Precipitation of cerous carbonate,
(Ce2(CO,)8). (o) To a solution of cerium chloride add a
solution of sodium or potassium carbonate. Note the
comparative insolubility in excess.

(6) Repeat the experiment, using ammonium carbonate
as the precipitant.

{c) Try the action of the common acids upon the car-
bonate of cerium.

Experiment 37. Precipitation of cerium oxalate^
(Ce^CCjO^),). (a) To a solution of a ceritim salt add oxalic
acid or an oxalate. Note the crystalline character of the pre-
cipitate, especially after the liquid has been stirred and boiled.

(6) Try the action of hydrochloric acid upon cerium
oxalate.

Experim^ent 38. Precipitation of the double sulphate
of cerium and potassium or sodium, (CejCSOjg- 3X380^ or
CejCSOJj-NajSOJ. To a few drops of a concentrated
solution of a cerous salt add a small pr^rtion of a saturated
solution of sodium or potassium sulphate.

44 THE RARER ELEMENTS.

Experiment 39. Precipitation of cerium phosphate^
(CePOJ. (a) To a solution of a cerous salt add sodium
phosphate in solution.

{b) Try the action of hydrochloric and acetic acids
upon separate portions of the precipitate.

Experiment 40. Precipitation of cerous -fluoride, (CeF,).
To a solution of cerium chloride add potassium fluoride in
solution.

Experiment 41. Precipitation of the ferrocyanide of
cerium, (Ce4(FeCeNe)8). (a) To a solution of cerium chloride
add potassium ferrocyanide.

(6) Note that potassium ferricyanide gives no pre-
cipitate.

Experiment 42. Comparison of lanthanum and didym-
ium with cerium, (a) Perform Experiments 35 to 41
inclusive upon dilute solutions of lanthanum and didym-
ium salts.

(fc) Note that ptire lanthanum and didymiimi salts
give no change of color with oxidizing agents. Compare
with cerium salts (vid. Experiment 34).

Experiment 43. Didymium absorption spectrum. Place
a solution of a didymium salt between the slit of the
spectroscope and a luminous flame. Note the dark bands.
Observe that cerium and lanthanum salts in solution show
no absorption bands when free from didymium.

Experiment 44. Negative test of the salts of cerium,
lanthanum, and didymium. Note that hydrogen sulphide
gives no precipitate with salts of this group. Ammonium
sulphide precipitates the hydroxides, not the sulphides.

THORIUM, Th, 232.5.

Discovery. As early as the year 181 8 Berzelius, after
working on a mineral from Fahlim, Sweden, believed that
he had discovered a new earth (Annal. der Phys. u. Chem.

THORIUM. 45

(i8i8) XXIX, 247). He gave it the name Thoria, from
Thor, son of the Scandinavian war god Odin. Some years
later however, he identified the supposed new earth as
chiefly a basic phosphate of yttritim (Pogg. Annal. iv,
14s). In 1828 Esmark discovered, near Brevig, Norway,
the mineral since known as thorite. From it Berzelius
isolated an tmknown earth; its similarity to the substance
described by him some ten years eariier prompted the
name Thoria (Pogg. Annal. xvi, 385).

Occurrence. Thoriimi is foimd in combination in cer-
tain rare minerals :

Contains ThO,

Thorite or orangite, ThSiO^ 48-72 %

YttriaKte, R303-2Si02 12%

Zircon, ZrSiO^. o- 2%

II III

Orthite or allanite, HRRgSijOjg o- 3%

Mackintoshite, U02-3Th02-3Si02-3H20 45-46%*

Thorogummite, UOj-3Th02-3Si02-6H30 41-42%

Caryocerite, complex silicates 13-14%

Tritomite, '" '* .\ 8-9%

ZirkeUte, (Ca,Pe)0-2(Zr,Ti,Th)02 7-8%

Monazite, (Ce,La,Di)PO^ 0-18%

Xenotime, YPO^ o- 3%

III III
Mschynite, R,Nb,0„ • R,(Ti,Th),0„ 15-1?%

Ill III

Euxetiite, R(NbO,), • R,(TiO,)3 • f H,0 o- 6 %

Tscheflfkinite, complex silicotitanates 0-21 %

Pyrochlore, RNb,0, • R(Ti,Th)0, 0-8%

II III

Samarskite, R3R3(Nb,Ta)eOai o- 3%

Annerodite, formula doubtful 2- 3 %

Polymignite, sRTiO, • sRZrO, • R(Nb,Ta)aOe 3-4%

♦ThO,+Ce,Oi.

46 THE RARER ELEMENTS.

Extraction, Two common methods for the extraction

of thorium salts are here indicated;

(i) From thorite. The mineral is decomposed by
heating it with sulphuric acid ivid. Experiment 33). After
the extraction of the sulphate with cold water, the solution
is heated to 100° C. and an impure sulphate of thorium
comes down. By repeated solution of the precipitate in
cold water and reprecipitation by means of heat a pure
sulphate is finally obtained (Delafontaine, Ann, Chem.
Pharm. cxxxi, 100). I

(2) From monazite. The mineral is decomposed by
sulphuric acid and the oxalates are precipitated by oxalic
acid {vid. Experiment 45).

The Element. A . Preparation. Elementary thorium
may be obtained (i) by heating the double chloride o£
thorium and potassium with metallic sodium (Nilson)
(2) by reducing the double fluoride of potassium and'
thorium with potassium.

B. Properties. Thorium is known in two forms, (1)
that of a grayish, glistening powder, and (2) crystalline.
It is stable in the air, and does not decompose water, even
at 100° C. When heated in a current of chlorine, bromine,
or iodine it glows and forms the salt. It is soluble in
dilute hydrochloric and sulphuric acids, in concentrated
sulphiunc acid with the liberation of sulphur dioxide, and
in aqua regia. It is acted upon very slowly by nitric
acid, and is not attacked by the alkali hydroxides. Thfti
specific gravity of thorium in the amorphous condition'
is 10.97; ill crystalline form 11. 2.

Compounds. A. Typical forms. The following are typ-
ical compounds of thorium:

Oxides, ThO,; Th,0,.
Hydroxide. Th(OH),.
Chlorides, ThCl,; also double salts with KCl and'NH.Cl.

I

THORIUM. 47

Bromide, ThBr,.

Iodide, ThI,.

Fluoride, ThF, + 4H,0.

Chlorate, Tli(C10J,.

Perchlorate, Th(C10j4.

Bromate, Th(BrOJ^.

lodate, Tli(IO,)^.

Sulphite, Th(SO,), + H,0.

Stdphates, Th(S0J, + 9H,0; also double salts with K,SO^;

Na,SO,; and (NHJ,SO,.
Selenite, ThCSeO^, + H,0.
Seleniate, Th(SeO,), + 9H,0.
Nitrate, Th(N03), + i2H,0.
Phosphate, Th3(POJ, + 4H,0.
Pyrophosphate, ThP,0, + 2H,0.
Ferrocyanide, ThFe(CN)e+4H,0.
SiUcate, ThSiO,.

Carbonates, ThCCO,),; Th(COg),-3Na,C03 + i2H,0.
Oxalate, Th(C20,)j+2H,0.
Sulphide, ThS^.

B, Characteristics, The compounds of thorium resem-
ble in chemical form those of cerium in the eerie con-
dition. Thorium resembles cerium also in having a hy-
droxide insoluble in the alkali hydroxides, and in forming
a double sulphate with potassixmi sulphate, insoluble in
excess of that precipitant. The salts of thorium are colorless
except where the element is combined with an acid having a
color of its own. Possibly the most distinctive reactions of
thorium compounds are the ready formation of a soluble
double oxalate when ammonium oxalate is added in excess
to a thorium salt in solution, and the precipitation of the
hydroxide when a solution of a thorium salt is boiled with
potassium hydronitride (Dennis and Kortright, Amer.
Chem. Jour, xvi, 79).

Estimation. Thorium is ordinarily estimated as the

THE RARER ELEMENTS.

oxide (ThOj), obtained by ignition of the hydroxide,
nitrate, or the oxalate.

Separation. Thorium is a member of the aluminuiU
group. Together with the rare earths cerium, yttrium,'!J
zirconium, etc., it may be separated from other membei
of the group by oxalic acid. Methods for its separatioifc
from yttrium and cerium have already been given (in
pages 24 and 35).

From zirconium thorium may be separated (i) by t
action of acids upon the potassium double sulphates,— •■
the zirconium salt being the more soluble; (2) by the action |
of an excess of oxalic acid upon the oxalates, — the zir-
conium oxalate dissolving first; (3) by fusion with acid
potassium fluoride; (4) by the action of dimethylamine
upon solutions of the salts, — thorium hydroxide being pre-j
cipitated {Kolb, J. pr, Chem, [2] lxvi, 59).

EXPERIMENTAL WORK ON THORIUM.

Experiment 45. Extraction of thorium oxide from monOrM
zite. Treat 25 grm. of finely ground monazite with com-l
mon sulphuric acid according to the method already ■
described (vid. Experiment 33). Precipitate the oxalate
with oxalic acid, — not ammonium oxalate, — boil, and col|
lect on a filter. Treat the precipitate with a large excesi
of ammonium oxalate and boil. Cool, filter, and to th(
filtrate add hydrochloric acid. Collect and ignite thel
oxalate of thorium thus precipitated.

Note. This method may be employed for the extractioi
of thorium from discarded Welsbach-hght mantles.

Experiment 46, Precipitation of thorium kydroxidt
(Th(OH)j). (a) To a solution of a thorium salt add sodiura,^
potassium, or ammonium hydroxide. Note the insolu-T
bility of the hydroxide in excess of the precipitant.

(b) To a solution of a thorium salt add sodium thio-
sulphate in solution and boil.

EXPERIMENTAL U^ORK OS THORIUM. 49

Experiment 47. Precipitation of tJiorium carbonate,
(Th(CO,)J. (a) To a solution of a thorium salt add
potassium or sodium carbonate. Note the solubility of
the precipitate in excess and the reprecipitation on boiling.

(6) Repeat, using ammonium carbonate.

(c) Note the solvent action of the common acids upon
thorium carbonate.

Experiment 48. Precipitation of the oxalate of tJioriiim,
(Th(C,0J, + 2H,0). (a) To a solution of a thorium salt
add a solution of oxalic acid. Note the insolubility in
excess of the precipitant.

(6) Repeat, using ammonium oxalate as the precipitant.
Note the solubility in excess, especially on warming, and
the reprecipitation upon the addition of hydrochloric acid.

(c) Try the solvent action of ammonium acetate upon
thorium oxalate.

Experiment 49. Precipitation of the double sulphate
of potassium and thorium, (Th(SOj2-2KjSO^ + 2H20 or
Th(SO J2 • 41^80^ + 2H2O) . Saturate a solution of a thorium
salt with potassium sulphate. (The corresponding sodium
salt (ThCSOJj-NajSO. + eHjO) is somewhat soluble in
excess of sodium sulphate.)

Experiment 50. Precipitation of thorium phosphate,
(Th3(POj4 + 4H20). To a solution of a thorium salt add
sodium phosphate in solution. Orthophosphoric acid is
said to precipitate an acid phosphate (ThHjCPOJj).

Experiment 51. Precipitation of thorium fluoride,
(ThF^ + 4H20). To a solution of a thorium salt add a
solution of potassium fluoride. Double salts with thorium
fluoride may also form {pcKY^yThF^ typical).

Experiment 52. Precipitation of thorium ferrocyanide,
(ThFe(CN)e + 4H20). To a solution of a thorium salt add
a solution of potassium ferrocyanide. Note the absence
of precipitation with potassium ferricyanide.

Experiment 53. Action of hydrogen peroxide upon

so THE RARER ELEMENTS.

salts of thorium. To a solution of a thorium salt add \
little hydrogen peroxide, and warm.

Experiment 54. Negative test of thorium salts. To 1
solution of a thorium salt add hydrogen sulphide. Note
thab ammonium sulphide precipitates the hydroxide, not
the sulphide. ^h

ZIRCONIUM, Zr, 90.7. ' ^|

Discovery, While engaged in the analysis of the
zircons, in 1788, Klaproth found one variety containing
31-5% of siUca, 0.5% of the oxides of iron and nickel,—
and 68% of an earth which differed from all earths pre
viously known to him. He observed that it was solubld
in the acids, but insoluble in the alkalies, in the latte
respect differing from alumina (Ann. de Chim. 1, 238)J
The fact that zircon was the source of the new earth sug>a
gested the name Zirconium for the element.

Occurrence. Zirconium is found combined, widely c
fused, but always in small quantities.

Contains Zt<]

Zircon, ZrSiO, 6n57^

Rosenbuscbite, 6CaSiO,-2Na,ZrO,F,-(TiSiO,-TiO,) 18-20^,

Lavenite, R(Si,Zr)0.-Zr(SiO,),-RTa,0, 28-32^

Wi'hlerite, i2R(Si.Zr}0,-RNb,0, 15-23%!

Hainite, allied to lavenite, etc undetermin

Hiortdahlite, 4Ca(Si,Zr)0,-Na,ZrO,F, 31-32^

Eudialyte, Na,3{Ca,Fe),Cl(Si,Zr)„0„ ii-i7?i

Catapleiite, H,(Na,,Ca)ZrSi,0„ 29-40^

Elpidite, H,Na,ZrSi„0., 20-21^

Eucolite, vid. Eudialyte 12-

Auerbachite, vid. Zircon 38-69^

Cyrtolite, " " 41-42%

Alvite, " " 48-Si%_

Tritomite, complex silicates 1-

Erdmannite, " " o~ S5?

ZIRCONIUM. SI

Contains ZrO|

Polymignite, sRTiO,-sRZrO,R(Nb,Ta),0, 29-30%

Arrhenite, complex 3- 4%

SipyUte, " 2-3%

ZirkeUte, (Ca,Pe)0-2(Zr,Ti,Th)03 52-53%

Baddeleyite, ZrO, 96 . 5%

Extraction. Zirconium salts may be extracted from
zircon by the following methods:

(i) The finely powdered mineral is fused with acid
potassium fluoride {vid. Experiment 55) (Marignac, Ann.
Chim. Phys. [3] lx, 257).

(2) The mineral is fused with potassium bisulphate
and the fused mass extracted with dilute boiling sulphuric
acid. The basic sulphate (3ZrO-S03) is left as a residue
(Franz, Ber. Dtsch. chem. Ges. 11, 58).

(3) The finely powdered mineral is heated with a mix-
ture of sodium hydroxide and sodium fluoride, the mass
is cooled, pulverized, and extracted with . water. The
residue, which consists mainly of sodium zirconate, is
digested with hydrochloric acid tmtil dissolved. After
the solution has been evaporated to a small volume the
zirconium oxychloride separates in crystalline form (Bailey,
Proc. Royal Soc. xlvi, 74).

The Element. A. Preparation. Elementary zirconium
maybe obtained in the amorphous condition (i) by reducing
potassium fluozirconate with potassium (Berzelius), and (2)
by reducing the oxide with magnesium (Phipson). It may
be obtained in crystalline form by heating potassium
fluozirconate with aluminum (Troost), and in graphitic
form by heating sodium fluozirconate with iron at 850° C.

B, Properties, (i) Zirconium in the amorphous con-
dition is a black powder. Heated in the air it bums
brightly to the oxide. It oxidizes also when fused with
alkali nitrates, carbonates, and chlorates, and is only
slightly attacked by acids.

vS»

THE RARER ELEMENTS.

(2) In crystalline form zirconium has much the ap-
pearance of antimony. Heated in the air it oxidizes very
slowly. It is not acted upon by fusion with alkali nitrates,
.carbonates, or chlorates, but is soluble in the acids upon
the application of heat. Its specific gravity is 4.15.

Compounds. A. Typical forms. The following are
typical compounds of zirconium;

Oxides, ZrO,; ZrO..

Hydroxide, Zr(OH},.

Chlorides, ZrCl, ; also double salts with KCl and NaCl.

Oxyhalides, ZrOCl,+3H,0 ; ZiOBr,+3H,0; ZrI(0H),+3H,0.

Bromide, ZrBr,,

Iodide, Zrl,.

Fluoride, ZrF,.

Sulphite, ZrCSO,),.

Sulphates, Zr{SO,)3 + 4H,0; 3ZrO,-SO,.

Selenite, Zr(SeO,),.

Nitrate, Zr{NO,), + 5H,0-

Phosphate, Zr,(PO,),,

Pyrophosphate, ZrPjO,.

Carbonate, 3ZrOj-CO, + 8H,0.

Oxalates, Zr(C,0J,2Zr(0H).; Zr(CpJ,K,C,O.HAO,-(-

8H,0.
Zirconates, Na.ZrO,; Li,ZrO„ etc.
Fluozirconate, K,ZrF,.

B. Characteristics. In chemical structure the com-
pounds of zirconium bear a strong resemblance to those
of thorium, titanium, germanium, and silicon. The oxide,
in its behavior as a base toward oxides having more acidic
qualities, resembles the oxide of thorium (ThOJ. With
the weaker acids, carbonic and oxalic, it shows weaker
basic properties in the formation of basic salts. With
strong bases it manifests acidic properties, like the oxide
of titanium, and forms zirconates (vid. Typical Forms,

ZIRCONIUM. S3

above). The hydroxide of zirconium is insoluble in excess
of the alkali hydroxides, the double sulphate with potas-
sium is insoluble in a solution of potassium sulphate, and
the oxalate is soluble in ammonium oxalate. Solutions
of pure zirconium salts are said to give no precipitate with
hydrofluoric acid or potassium hydronitride. Turmeric
paper, when dipped into a solution of a zirconiimi salt and
dried, is colored orange.

Estimation. Zirconium is usually weighed as the oxide
(ZrO,) obtained by ignition of the hydroxide or oxalate.

Separation. Zirconium is a member of the aluminum
group, and with the rare earths may be roughly separated
from other members of the group by the action of oxalic
acid {md, page 24). For the separation from yttrium,
cerium, and thorium see tmder those elements. The sepa-
ration of zirconium from iron and titanium has received a
good deal of attention from chemists. Some of the methods
that have been suggested follow.

From iron zirconium may be separated (i) by the action
of water upon an ethereal solution of the chlorides, — the
oxychloride of zirconium being precipitated (Matthews,
Jour. Amer. Chem. Soc. xx, 846); (2) by the action of
gaseous hydrochloric acid and chlorine at a temperature of
about 200° C. upon the mixed oxides, — the ferric chloride
being volatilized (Havens and Way, Amer. Jour. Sci. [4]
VIII, 217); (3) by treatment with phenylhydrazine, — the
zirconium being precipitated (Allen, Jour. Amer. Chem.
Soc. XXV, 426) ; (4) by the action of sulphurous acid
on neutral solutions, — ^the zirconium being precipitated
(Baskerville, Jour. Amer. Chem. Soc. xvi, 475).

From titanitun zirconitim may be separated d) by
boiling a solution containing the two elements with dilute
sulphuric and acetic acids, — ^titanic acid being precipitated
free from zirconium (Streit and Franz, J. pr. Chem. cviii,
75; Zeitsch. anal. Chem. ix, 388); (2) by treating solu-

tions acid with sulphuric or hydrochloric acid with zinc
until the titanium is reduced to the condition of the sesqui-
oxide, and then adding potassium sulphate, — the zircomum-
potassium sulphate being precipitated iPisani, Compt.
rend, lvii, 298; Chem. News x, 91, 218); (3) by adding
ammonium hydroxide to a boiling hydrofluoric acid solu-
tion of the salts,- — the titanic acid being precipitated
(Demarcay, Compt. rend, c, 740; J. B. {1885), 1929).

EXPERIMENTAL WORK ON ZIRCONIUM.

Experiment 55. Extraction of zircaniKm salts from
sircon. Fuse 5 grm. of finely powdered zircon in a platinum
or nickel crucible with about 15 grm. of acid potassium
fluoride. Pulverize the fused mass and extract with hot
water containing a few drops of hydrofluoric acid.* Filter
immediately through a rubber funnel into a rubber beaker.
As the filtrate cools, potassium fluozirconate crystallizes
out. It may be purified by recrystallization.

Experiment 56. Precipitation of zirconium hydroxide,
(ZrCOH)J. (a) To a solution of a zirconium salt add potas-
sium, sodium, or ammonium hydroxide. Note the insolu-
bility in excess. (&) To a solution containing zirconiimi add
sodium thiosulphate in. solution and boil.

Experiment 57. Precipitation of zirconium carbonate,
(aZrOj-COj + SHjO). (o) To a solution of a ziic^um
salt add sodium or potassiimi carbonate. Note the partial
solubility in excess.

(6) Use ammoniimi carbonate as the precipitant. Note
the solvent action of an excess and the precipitation of
the hydroxide on boiling.

(c) Try the action of the common acids upon separate
portions of zirconiimi carbonate.

porcelain dishes must not be used when hydrofluoric add i

I

I

1

GERMANIUM. 55

Experiment 58. Precipitation of zirconium oxalate,
(ZrCCjOJj-aZrCOH),). (a) To a solution of a zirconium
salt add a solution of oxalic acid. Note the effect of an
excess in the cold and on wanning.

(6) Use ammonium oxalate as the precipitant. Note
the solvent action of an excess and the reprecipitation by
ammonium hydroxide.

Experiment 59. Precipitation of zirconium phosphate,
(xZrOj-yFfi^, basic). To a solution of a zirconium salt
add sodium phosphate. Ortho phosphoric acid precipi-
tates the normal phosphate (ZrjCPO,)^).

Experiment 60. Precipitation of zirconium ferrocyanide,
(ZrFeCgNg?), To a solution of a zirconium salt add potas-
sium ferrocyanide.

Experiment 61. Action of zirconium salts upon turmeric
paper. Dip a piece of turmeric paper into a solution of a
zirconium salt acidified with hydrochloric acid. Dry on the ,
side of a test-tube or beaker, as in testing for boric acid. '
Note the yellowish-red color.

Experiment 62. Negative tests of zirconium salts. Note 1
that neither hydrogen sulphide nor potassium fluoride gives 1
a precipitate with zirconium salts. Ammonium sulphide 1
precipitates the hydroxide, not the sulphide.

GERMANIUM, Ge, 72.

Discorery. In 1886 Clemens Winkler annoimced the
presence of a new element in the silver mineral argyrodite,
which had been discovered the previous year by Weisbach,
in the Himmelsfurst mine near Freiberg ( Ber. Dtsch,
chem. Ges. xix, 210). According to Winkler's analysis
of argyrodite, the sum of its component parts was seven per
cent, less than it should have been ; and although he re-
peated the analysis several times with great care, the out-
come was always the same. This imiformity of result forced

56

THE RARER ELEMENTS-

upon him the conclusion that an unknown element ■^
probably present; and after much careful and patient work I
he was successful in isolating it and investigating its prop- "
erties. On heating the mineral out of contact with the air,
he obtained a dark-brown fusible sublimate, which proved
to be chiefly two sulphides, that of the new element, named
by him Germanium, and the sulphide of merciuy.

Occurrence. Germanium is found in combination in aj
few rare minerals.

Argyrodite, 4AgjS-GeSj ■. 6-??!

. £;aM/^Wi(e,4AgjS-(Ge,Sn)S, 1.82^

Euxenite, R(NbO,), ■ ^(^(TiOJ, ■ JH,0 trace!

Extraction, Germanium salts have been extracted^
from argyrodite by the following methods :

(i) A Hessian crucible is heated to redness, and smallj
quantities of a mixture consisting of three parts of sodiumi
carbonate, six parts of potassium nitrate, and five parts ofT
the mineral are gradually put in. After being heated iaei
some time the molten mass is poured into an iron dish anda
allowed to cool. The salt mass may then be removed froin
the silver, pulverized, and extracted with water. TheJ
extract is treated with sulphuric acid and evaporatei
until all the nitric acid is driven off. The residue is c
solved in water and allowed to stand imtil the oxide (
germanium separates from the solution,

(2) The mineral is heated to redness in a current (
hydrogen, and the sublimate, consisting of a mixture ofj
germanium and mercuric sulphides, is collected. Tli
sublimate is treated with ammonium sulphide, which dis^s
solves the sulphide of germanium, forming a sulpho salt J
After filtration, the solution is acidified with hydrochlbri
acid, which precipitates the germanium as the sulphide.

GERMANIUM. 57

The Element. A. Preparation. Elementary germanium
may be obtained (i) by heating the oxide with carbon;
{2) by heating the oxide in a current of hydrogen.

B. Properties. Germanium is a grayish-white, metallic
element, having a fine luster, and crystallizing in regtilar
octahedra. It volatilizes slightly when heated in hydrogen
or nitrogen at about 1350** C; its melting-point is about
900** C. In the air it does not oxidize at ordinary tem-
peratures, but when heated goes over to the oxide GeO^.
It is not attacked by dilute hydrochloric acid, is oxidized
by nitric add, and is dissolved by aqua regia. It is dis-
solved also by sulphuric acid, with the evolution of sul-
phur dioxide. It combines directly with chlorine, bromine,
and iodine. Its specific gravity is 5.46.

Compounds. A. Typical forms. The following are typ-
ical compounds of germanium:

Oxides GeO GeO,

Hydroxides Ge(OH), Ge(OH),?

Chlorides GeCl, GeCl,

Oxychloride GeOCl,

Bromide GeBr^

Iodide Gel^

Fluorides GeF,? GeF,?; K^GeF^; H,GeFe

Sulphides GeS GeS,

Chloroform GeHCl,

Ethyl Ge(C,HJ,

B. Characteristics, The germanium compounds are
known in two conditions of oxidation ; those of the higher
form are the more stable and comprise the larger group.
Germanium resembles carbon and silicon in the formation
of a chloroform, and tin in the formation of two sulphides
which dissolve in ammonium sulphide, giving sulpho salts.
The sulphide GeS, is a white powder slightly soluble in
water. The lower sulphide, GeS, when precipitated, is of a

jS THE RARER ELEMENTS.

reddish-brown color; when obtained by the reduction of the
higher sulphide it is a grayish-black crys' alline substance of
metallic luster. This sulphide, also, is slightly soluble in
water. The dioxide is a white powder soluble in alkalies, but
almost completely insoluble in acids. The tetrachloride is
a liquid which fumes in damp air and is decomposed by-
water.

Estimation. Germanium is usually precipitated as t
sulphide, converted by nitric acid into the oxide (GeO^^
and weighed as such.

Separation. Germanium may be separated from most
the elements by the formation of a soluble sulpho salt witJ
ammonium sulphide; when the solution is acidified thi
sulphide is precipitated. Germanium may be separate
from arsenic, antimony, and tin as follows: the solution c
the sulpho salts is exactly neutralized with sulphuric aci<^
allowed to stand twelve hours, and filtered; the filtrate i
evaporated to a small volume, treated with ammonia andj
sulphate of ammonium, acidified with sulphuric acid, and
saturated with hydrogen sulphide. Germanium sulphidi
is precipitated (Truchot, Les Terres Rares, 294).

TITAmUM, Ti, 48.1.

Discovery. In the year 1791 McGregor (Crell Annal. (i^QiS
1, 40, 103) discovered a new "metal" in a magnetic sanq
found in Menachan, Cornwall. This sand he named Men»
chinite, and the newly discovered element Menachite. Foi
years later Klaproth announced the discovery of a new eart
in a rutile which he was engaged in studying (Klapr. Beiti
ii 233). To the metal of this earth he gave the name Titfi
nium, in allusion to the Titans. In 1797, however,
found that titaniimi, was identical with menachite (Klapi
Beitr. 11, 236).

Occurrence. Titanium is found combined' in manS

TITANIUM. 59

minerals, but never in considerable quantity in any one
locality.

Contains TiO|

Rutile, TiO, / 90-100%

Dicksbergite, vid. Rutile 90-100%

Brookiie, TiO, 90-100%

Octahedrite, TiO, 90-100%

Pseudobrookite, Fe^(TiOJ, 44- 53%

Perofskite, CaTiO, 58- 59%

Ilmenite, FeTiO, 3- 59%

GeikieHte, MgO-TiO, 67- 68%

Senaite, (Fe,Pb)0 • 2(Ti,Mn)0, 57-58%

ZirkeUte, (Ca,Fe)0-2(Zr,Ti,Th)03 14- 15%

Knopite, RO-TiO, 54- 59%

DerbyUte, 6Fe0.5TiO,.SbA 34-35%

Lewisite, sCaO • 2TiO, • 3Sb305 i 11-12%

Mauzeliite, 4(Ca,Pb)0-TiO,-2Sb205 7- 8%

Titanite, CaTiSiOj 34- 42 %

I II

Neptunite, R^RTiSi.Oj, 17-^ 18%

Hainite, formula doubtful undetermined

Lamprophyllite, formula doubtful * '

Keilhauite, complex silicate 26- 36%

Schlormenite, 3CaO(Fe,Ti)203-3(Si,Ti)0, 12- 22%

Guarinite, CaTiSiOg 33- 34%

Tscheffkinite, complex silicates 16- 21 %

Astrophyllite, (Na,K),(Fe,Mn),Ti(SiO,), 7- 14%

Johnstrupite, complex silicates 7- 8%

Mosandrite, ' * * * 5- 10%

Rinkite, '* '' 13- 14%

Dysanalyte, 6(Ca,Fe)Ti03-(Ca,Fe)Nb,Oe 40- 59%

Pyrochlore, RNb20e-R(Ti,Th)03, 5- 14%

III III

yEschynite, R,Nb,0„-Rj(Ti,Th),0„ 21-22%

Polymignite, 5RTiO,-5RZrO,R(Nb,Ta),0, 18- 19%

6o THE R/iRER ELEMENTS.

Contalng Tf O,

Euxenite, R(NbO,),-Rj(TiO,),.fH,0 20- 23%

Polycrase, RCNbO,),-2R(TiOJ,-3H,0 25- 39%

Titanium has been found also in sand on the banks of the
North Sea, in some mineral waters, in certain varieties of
coal, in meteorites, and by means of the spectroscope it
has been detected in the atmosphere of the sim. It has
been foimd in the ash of oak, apple, and pear wood, in
cow peas, in cotton-seed meal, and in the bones of men
and animals. Vid. also Baskerville, Jour. Amer. Chem.
Soc, XXI, 1099.

Extraction. Titanium salts may be extracted from
rutile by the following methods:

(i) The mineral is fused with three parts of a mixture
of sodium and potassium carbonates and the fused mass
is extracted with water. The titanium, as a sodium or
potassium titanate, remains, together with £ome tin and
iron, in the insoluble residue. This mass is treated with
strong hydrochloric acid until dissolved. The solution is
then diluted, and the tin is removed by hydrogen sulphide.
The sulphide of tin is filtered off, the filtrate is made am-
moniacal with ammonium hydroxide and again treated
with hydrogen sulphide. The iron is precipitated as the
sulphide, and the titanium as the hydroxide. After filtra-
tion the precipitate is suspended in water and a current
of sulphur dioxide is passed through imtil the black sul-
phide of iron has dissolved, leaving the oxide of titanium.

(2) The mineml is fused with three parts of acid potas-
sium fluoride and the fused mass is extracted with hot water
and a little hydrofluoric acid. The titanium separates, on
cooling, as the potassium fluotitanate (K^TiFa + HjO).

(3) The mineral is fused with six parts of acid potassium
sulphate (vid. Experiment 63).

The Element. A. Preparation. Elementary titanium

TITANIUM.

6i

may be obtained (i) by heating potassium fluotitanate
with potassitim (Berzelius and Wohler); (2) by passing
the vapor of the chloride (TiCl^) through a bulb tube con-
taining sodium.

B, Properties, As prepared in the laboratory, tita-
nium is a dark-gray powder. It does not decompose water
at ordinary temperatures and acts on heated water but
slightly. When heated in the air it combines with the
oxygen, burning brightly to the oxide (TiOj); in oxygen
the combination is accompanied with brilliant light. Ti-
tanium is readily soluble in warm hydrochloric acid, and
is attacked by dilute hydrofluoric, nitric, sulphuric, and
acetic acids. It combines with chlorine. It combines also
with nitrogen, forming nitrides.

Compounds. A. Typical forms. The following are typ-
ical compotmds of titanium:

Oxides . . . TiO ; (Ti,0 J ; Ti^O, ; (Ti,0,,) ; TiO, ; (Ti,0,) ; TiO,

Hydroxides

Ti(OH), Ti(OH

Chlorides . .

Ti,Cle

. TiCl,

Bromide . . .

TiBr,

Iodide

Til,

Fluoride . . .

TiF,

Titanofluor-

I

ides

RjTiF,, etc.

Sulphides . ..

Ti.S,

TiS,

Nitrides. . . .

Ti,N,;Ti,N.;TiN,

Carbide ....

Tie

Titanates . . .

RTiO,; R^TiO,

Acids {vid. Hydroxides]

)...

H;rio,

B, Characteristics, Although a number of oxides of
titanitim are known, the dioxide is the form generally
found, and the salts of that type are by far the most numer-
ous and important. The oxide (TiOj) resembles the oxide
of zirconium (ZrOj) in acting as a weak base. It forms

/

/

62 THE R/IRER ELEMENTS,

salts with the strong acids, but does not combine with the

weak acids. It unites with the strong bases to form tita-
II I

nates, (RTiOg and R^TiO,). It has less basic and more
acidic properties than the oxide of zirconium. The tet-
rachloride is a colorless liquid which fumes in the air.
Titanium, in its behavior toward reagents, resembles quite
closely both niobium and tantalum, with which it is often
found associated ivid. Occurrence).

Estimation. A, Gravimetric. Titanium is usually pre-
cipitated as the acid, either by ammonium hydroxide
or by boiling a dilute solution acidified with acetic or
sulphuric acid; the precipitate is ignited and the element
is determined as the oxide (TiOj).

B. Volumetric, Titanium is estimated volumetrically
(i) by treating with hydrogen dioxide a definite amount
of the titanium solution to be determined and com-
paring its color with that of a definite amount of a
standard solution of titanium similarly treated (Weller,
Ber. Dtsch. chem. Ges. xv, 2592); (2) by reducing the
titanium from the dioxide to the sesquioxide condition,
by the use of zinc and hydrochloric acid, and then oxidiz-
ing it with permanganate (Osbom, Amer. Jour. Sci. [3]
XXX, 329).

Separation. The general method for the separation
of titanium from the other members of the. aluminum
group is to boil dilute acidified solutions {vid. Gravimetric
Estimation). The titanium precipitate, however, carries
down traces of other elements, as aluminum and iron.

From iron titanium may be separated (i) by passing
hydrogen sulphide into an alkaline solution to which am-
monium tartrate has been added, — the iron sulphide being
precipitated (Gooch, Amer. Chem. Jour, vii, 283) ; (2) by
treating a mixture of ferrous sulphide and titanic acid
with sulphur dioxide {vid. Extraction); (3) by boiling a
neutral solution with hydrogen dioxide, — metatitanic acid

EXPERIMENTAL IVORK ON TITANIUM. 63

being precipitated; (4) by treating a solution of the salts
with phenylhydrazine, — ^titanic acid being precipitated
(Allen, Jour. Amer. Chem. Soc. xxv, 421).

From aluminum titanium may be separated by boiling
a solution containing them, in the presence of an alkali
acetate and of acetic acid to about seven per cent, of the
whole solution, — titanium basic acetate being precipitated
(Gooch, Amer. Chem. Jour, vii, 283).

From cerium and thorium titanium may be separated by
precipitating the double sulphates of those elements with
potassium sulphate. Methods for the separation from
zirconium have already been given {vid. Zirconium). From
niobium and tantaltun titanium may be separated by
repeated fusions with acid potassium sulphate and extrac-
tions of the melt with water, — ^the titanium being in soluble
form.

EXPERIMENTAL WORK ON TITANIUM.

Experiment 63. Extraction of titanium salts from rutile,
(a) Mix 5 grm. of finely powdered mineral with about 30 grm.
of acid potassium sulphate and fuse until the mass is free
from black particles. Pulverize the fused mass and ex-
tract with cold water, stirring frequently until solution
is complete. Add ammonium sulphide, filter and wash.
Suspend the precipitate, which consists mainly of titanium
hydroxide and ferrous sulphide, in water and pass a cur-
rent of sulphur dioxide through the liquid imtil the ferrous
sulphide has dissolved, as shown by the disappearance
of the dark color. Filter, and wash the titanium hydroxide
which remains.

(6) Alternative method. After having dissolved the fused
mass in cold water {vid, (a)) add about 20 grm. of tartaric acid
to hold up the titanitun hydroxide, and make the solution
faintly ammoniacal. Pass hydrogen sulphide through until
the ferrous sulphide is completely thrown down. Filter, add

THE RARER ELEMENTS.

about lo cm.' of concentrated sulphuric acid to the filtrate,
and evaporate in a porcelain dish under a draught hood
until the tartaric acid is thoroughly carbonized. Allow
the mass to stand until cool, add water, keeping the hquid
cool to prevent the precipitation of the titanium hydroxide,
and decant from the carbon residue. Filter the brown
liquid through animal charcoal that is free from phos-
phates and precipitate the titanium hydroxide with am-
monium hydroxide (R. G. Van Name).

Experiment 64. Precipitation of titanium hydroxide,
CTi(OH),). (a) To a solution containing titanium add
sodium, potassium, or ammonium hydroxide. Note thd
comparative insolubility in excess, especially in ammo-j
niimi hydroxide.

ib) Repeat the experiment, using the alkali carbonates.,
The precipitate is the same as in (a).

(c) Note the solubility of the freshly precipitated hy-
droxide in the common acids.

{d) Ignite a portion of the precipitate and try its solu-
bility in acids.

Experiment 65. Precipitation of titanic hydroxide or
acid by boiling, (a) Boil a dilute acid solution of titanic
hydroxide. Note the precipitation. Filter, and test the;
filtrate with ammonium hydroxide.

(fc) To a solution of titanic acid containing enougli
free acid to prevent precipitation on boiling, add ammo-
nium acetate. Try similarly sodium thiosulphate.

Experiinent 66. Color tests of solutions containing
titanium, (a) To an acid solution containing titanium
add hydrogen dioxide. Note the yellow color {TiO, in
solution).

(i) To a solution containing titanium add a piece
metallic zinc and enough acid to start the action. Ni
the violet color which develops.

(c) To three portions of dry titanium oxide (TiOj)

NIOBIUM (COLUMBIUM); TANTALUM. 65

or double fluoride (K^TiFe) add a few drops of strong
sulphuric acid. Bring into contact with the first a few
particles of tannic acid, with the second a little dry pyro-
gallic acid, and with the third some morphia. Note the
red color.

Experiment 67. Negative test of titanium compounds.
Pass hydrogen sulphide through a solution containing
titanium. Note the absence of precipitation.

NIOBIUM (COLUMBIUM), Nb(Cb), 94; TANTALUM, Ta, 183.

Discovery. Hatchett, while working with some chro-
mium minerals in the British Museum in 1801, came across
a black mineral very similar to those upon which he was
engaged (Phil. Trans. Roy. Soc. (1802), 49). He obtained
permission to examine it and found it to consist almost
wholly of iron and an earth which did not conform to
any known test. He described it as **a white, tasteless
earth, insoluble in hot and cold water, acid to litmus,
infusible before the blowpipe, and not dissolved by borax. ' '
The only acid which dissolved it was sulphuric. Since
the mineral was of American origin, coming from Con-
necticut, the discoverer named it Columbite, and the
element Columbitmi.

About a year later Ekeberg (Crell Annal. (1803) i, 3),
while investigating a mineral from Kimito, Finland, which
closely resembled columbite, discovered a '' metal*' which
resembled tin, tungsten, and titanium. It proved to be
none of these, but in fact a new element. He named it
Tantalum, ** because even when in the midst of acid it
was unable to take the liquid to itself. ' ' Indeed, insolu-
bility in acid seemed to be the chief characteristic of the
new substance.

The apparent similarity of coltmibium and tantalum
suggested that they might be identical, and in order to

*6 THE RARER ELEMENTS.

solve this problem Wollaston {Phil. Trans. Roy. See.
xcix, 246) in 1809 began to work on tantalite and a speci-
men of the same columbite that Hatchett had examined.
He foimd that the freshly precipitated acids were both
soluble in concentrated mineral acids; if they were dried
it was necessary to fuse them ix)th with caustic alkalies
before they could be dissolved. Both were held up i£
ammonium hydroxide was added in the presence of citric,
tartaric, or oxalic acid. Having found practically the same
reactions with both acids, he concluded that the elementary
substances were the same. The specific gravity of tantalite,
however, was 7.95, and that of columbite 5.91. This he
explained by suggesting different conditions of oxidation
or different states of molecular structure. These con-
clusions were accepted, and for many years the element
was called indifferently tantalum and columbium.

In 1844 Rose began to investigate the same subject.
His work on the columbites of Bodcnmais and Finland
led him to the behef that there were two distinct acids
in the columbite from Bodcnmais, one similar to that in
tantahte, the other containing a new element, to which
he gave the name Niobium, from Niobe, daughter of Tan-
talus. Though niobium proved to be Hatchett 's colum-
bium, Rose 's name for the element has been the one more
generally adopted.

Occurrence. Niobium and tantalum are foimd, each
in combination, in various rare minerals. They usually,
though not invariably, occur together.

Con tains
Nb,0( Ta,Oi

Pyrocklore, RNb,Oa'RfTi,Th)0, 47-58%

Koppite. R,Nb,0,-|NaF 61-62%

Hatchettolite, '

2R(Nb,Ta)308-R;CNb,Ta),0,. ........ 63-67%*

*Nb,Os + TajO,-

NIOBIUM (COLUMBIUM); TANTALUM. 67

Contains
Nb,0, Ta,(\

Microlite, Ca,Ta,0, 7-8% 68-69%

Fergusonite, (Y,Er,Ce)(Nb,Ta)0. 14-46% 4-43%

SipyUte, RNbO« 47-48% i- 2%

Columbite, (Fe,Mn)(Nb,Ta),0, 26-77% 1-77%

Tantalite, FeTa,0, 3-40 ';'o 42-84%

SkogboUte, " 3-40% 42-84%,

TapioHte, Fe(Nb,Ta),0, ii-i2 9o 73-74%

Mossite, Fe(Nb,Ta),0, 83%*

n m

Yttrotantalite, RR2(Ta,Nb),0„ 12-13% 46-47%

ni II

Samarskite, R,R,(Nb,Ta),0„ 4i-56<:;, i4-i8<:;,

StibiotantaUte, Sb,0,(Ta,Nb),05? 7 5% 5 1 %

o

Annerodite, complex 48-49%

Hielmite, complex 4-16% 55-72%

III III

^schynite,R,NbA,-Ra(Ti,Th)As 32-33% 21-22%

Polymignite,

sRTiO, • sRZrO, • R(Nb,Ta) ,0, 11-12% i - 2 %

III III

Euxemte, R(Nb03),-R,(Ti03),-|H,0 18-35%

ni III

Po/ycro^^, R(Nb03)3.2R,(Ti03)3.3H30... 19-25% 0-4%

Wohlerite, i2R(Si,Zr)03.RNb30e 12-14%

Lavenite, R(Si,Zr)03 • Zr(Si03)2 • RTa^Oe. . o- 5 %*

Dysanalyte, eRTiOg • RNb^Oe 0-23% 0-5%

Eucolite, complex silicates 2- 4%*

Melanocerite, complex silicates 3-4%

Tritomite, complex silicates 1-3%

Cassiterite (ainalite) , SnOj o- 9 %

Extraction. Salts of niobium and tantalum may be
extracted from columbite or tantalite by either of the fol-
lowing methods:

♦NhjOj+TaaOj.

THE RARER ELEMENTS.

(i) The mineral is fused with six parts of potassium
bisulphate, the fused mass is pulverized and treated with
hot water and dilute hydrochloric acid. The residue is
then digested with ammonium sulphide to remove tin, timg-
sten, etc., and again warmed with dildte hydrochloric acid.
After this treatment it is washed thoroughly with water
and dissolved in hydrofluoric acid. Filtration is followed
by the addition of potassium carbonate to the clear solu-
tion until a precipitate begins to form. The potassium
and tantalum double fluoride separates first in needle-
like crystals, after which the niobium oxyfluoride crys-
tallizes in plates.

(2) The mineral is fused with three parts of acid potas-
sium fluoride {vid. Experiment 68).

The Elements. I, Niobium. A. Preparation. The ele-
ment niobium may be obtained by reducing the chloride
with hydrogen at a high temperature (Bloomstrand) .

B. Properties. Niobium is a metallic element of
steel-gray color and brilliant luster. Heated in the air
[ it ignites; heated in chlorine it forms the chloride (NbClj).
It is very slightly soluble in hydrochloric acid, nitric acid,
and aqiia regia, but dissolves in concentrated sulphuric acid
upon the application of heat. Its specific gravity is 7.06.

II. Tantalum. A. Preparation. Elementary tanta-
lum may be obtained by heating the potassium and
tantalum fluoride (KjTaFj) with potassium and extract-
ing the potassium fluoride with water.

B. Properties. Tantalum in the elementary condition
' is a black substance with a metallic luster. Like niobium
it ignites when heated in the air and forms the chloride,
(TaCls), when heated in chlorine. It is insoluble in hydro-
chloric, nitric, and sulphuric acids, and in aqua regia, but
dissolves in hydrofluoric acid. Its specific gravity is 10.78,

Compounds. A. Typical forms. The following are typ-
ical compotinds of niobium and tantalum:

NIOBIUM {COLUMBIUM); TANTALUM. 69

Oxides. Nb,0,

Nb,0« Ta,0.

Nb,0, Ta,0,

Chlorides NbCl,

NbCl, TaCl,

Oxychloride NbOCl,

Bromides. NbBr, TaBr,

Oxybromide. . . . NbOBr,

Fluorides NbF, TaF,

Oxyflupride NbOF,

Fluotantalates . . K,TaF,

Na,TaF,

(NH,),TaF,

Double fluorides . «KF-yNbOF,) ,. . ,.

*KF.jNbO,FM*yPical)

Sulphide Ta,S«

Oxysulphide. . . . Nb,OS,

Nitride Ta,N,

Niobates KgNb.O„ + 1 6H,0

K.Nbp,. + i3H,0

aKjNb.O^ + iiHjO

K,Nb,0, + iiH,0

Na,.Nb,A,

Na,Nbp„ etc.

Tantalates Of tj^jes RgTaeO,, and RTaO,,

with Na , K, NH^, Ba, and Mg.

B. Characteristics. The compounds of niobium closely
resemble those of tantalum, both in chemical form and in
behavior toward reagents. The two elements are closely
associated in minerals {vid. Occtirrence) . The lower oxides
of niobium are dark powders which oxidize when heated.
The dioxide is soluble in hydrochloric acid, while the tetrox-
ide is not attacked by acids. The pentoxide is a yellowish-
white amorphous powder somewhat soluble in concen-
trated sulphviric acid before ignition, but insoluble after.

THE RARER ELEMENTS.

Niobium pentachloride is a yellow crystalline substance
■which tends to form the oxychloride in the presence of
■water, and is reduced to the trichloride when its vapor is.
passed through a red-hot tube. The fluoride is formed by
the action of hydrofluoric acid upon the pentoxide.

Tantalum tetroxide is a very hard, dark-gray, porous
mass which is not attacked by acids. When heated it
goes over to the higher oxide. The pentoxide of tanta-
lum is a white powder which is somewhat soluble in acids.
The chloride and fluoride of tantalum are formed similarly
to the corresponding salts of niobium and resemble them
in general behavior. Niobates and tantalates are obtained
by fusing the oxides with caustic alkahes; these salts are
soluble. The tantalum compounds give no color test with
morphia, tannic acid, or pyrogallic acid.

Estimation. A. Gravimetric. Niobium and tantalum
are ordinarily weighed as the oxides NhjO^ and Ta,0(,
obtained from ignition of the acids.

B. Volumetric. Niobium may be estimated volumet-
rically by reduction from the condition of the pentoxide to
that of the trioxide by means of zinc and hydrochloric
acid in a current of carbon dioxide, and oxidation with
permanganate (Osbom, Amer. Jour. Sci. [,5] xxx, 329).

Separation. The method usually employed for the
separation of niobium and tantalum from the elements
with which they are generally associated — namely, tita-
nium, zirconium, and thorium- — is that of fusion with acid
potassium sulphate (vid. Titanium). From tin and tung-
sten they may be separated by ammonium sulphide.

The separation of niobium from tantalum is one of
the most difficult of analytical problems, Marignac's
method (Ann. Chim. Phys. [4] viii, i), based upon the
difference in solubility * between the tantalum-potassium

*KiTaF, 13 soluble in 151-157 parts o( cold water. 2KF-NbOF,-|-H,0
ia sotuble in 13-13 p^rta of cold water.

EXPERIMENTAL IVORK ON NIOBIUM AND TANTALUM. 11

fluoride (K^TaF^) and the niobium-potassium oxyfluoride
(2KF-NbOF3 + H20), is the most satisfactory known.

EXPERIMENTAL WORK ON NIOBIUM AND

TANTALUM.

Experiment 68. Extraction of niobium and tantalum
salts from columbite or tantalite. Mix 5 grm. of the finely
ground mineral with 15 grm. of acid potassium fluoride
and fuse thoroughly. Pulverize the fused mass and extract
with boiling water containing a little hydrofluoric acid.
Evaporate to about 200 cm.' and allow the liquid to stand.
The potassium and tantalum fluoride separates first in
needle-like form; the niobium and potassium oxyfluoride
crystallizes in plates on concentration of the solution.
The salts of the two elements should be purified as far as
possible by fractional crystallizations.

Experiment 69. Preparation of niobic and tantalic
oxides {acids), (NbjOg; TajOg). (a) Evaporate a solution
of potassium and niobium oxyfluoride to dryness, add strong
sulphuric acid, and heat until all the hydrofluoric acid
is expelled and a solution is obtained. Cool the solution,
dilute with water, and boil. Niobic acid, (NbjOJ, is pre-
cipitated. Filter, and test the filtrate with ammonium
hydroxide.

(6) Repeat the experiment, using a solution of potas-
sium and tantalum fluoride instead of the niobium salt.

(c) Test the action of alkali hydroxides or carbonates
in excess upon solutions of niobium and tantalum obtained
in (a) and (6).

Experiment 70. Action of fusion with sodium or potas-
sium hydroxide upon niobic and tantalic acids, (a) Melt
a gram of sodium or potassium hydroxide in a hard glass
tube, add a small quantity of dry niobic acid, and heat
again. Note that the fused mass is soluble in water.

7» THE RARER ELEMENTS.

(b) Repeat the experiment, using dry tantalic
instead of niobic.

(c) Acidify portions of the solutions obtained in (a) I
and (fc).

Experiment 7 1 . Color tests for niobium, (a) Treat I
separate portions of dry niobic oxide (or acid) with t
acid, pyrogallic acid, and morphia, as in Experiment 66 (c) J
Note the brown color.

(b) Repeat the experiment, using tantalic oxide inst
of niobic. Note the absence of color.

(c) Try the action of metallic zinc upon an acid solu-l
tion containing niobium.

Experiment 72. Negative tests of niobium and tanialuni^M
Note that hydrogen sulphide gives no precipitate, and]
that hydrogen peroxide gives no yellow color with acidl
solutions containing niobium or tantaliun,

IHDIUM, In, 114.

Discovery. Indium was discovered by Reich andl
Richter in 186,^, in the course of an examination of twoj
ores consisting mainly of the sulphides of arsenic, zinc,W
and lead (J. pr, Chem. lxxxix, 441). These ores had been
freed from the greater part of their arsenic and sulphur
by roasting, and the residue had been evaporated to dry-
ness with hydrochloric acid and distilled. The crudej
chloride of zinc thus obtained was examined with thi
spectroscope for thallium, since the presence of that elemenll
■had been indicated in similar ores from the Freiberg minea
Instead of the thallium line, however, appeared one 1
indigo blue never before observed. The color suggested
the name Indium for the tmknown element present.

Occurrence. Indium occurs in very small amountJ
combined with sulphur, in many zinc-blendes. It has t
found in zinc-blende from Freiberg and Breitenbrun iA

INDIUM. 73

Saxony, and from Schonfeld in Bohemia ; in christophite, a
variety of zinc-blende; in zinc prepared from these ores;
and in the flue-dust from ovens used for roasting zinc ores.
It has also been fotind in wolframite from Zinnwald. The
proportion of indium in the minerals named varies from
one tenth of one per cent, to mere traces. Lockyer de-
tected it in the atmosphere of the stm. Hartley and Ra-
ilage (Jour. London Chem. Soc. (1897), 533, 547) have dis-
covered it spectroscopically in many iron ores, — notably
siderites, — in some manganese ores, in zinc-blendes, in
five tin ores examined, and in many pyrites.

Extraction. Indium salts may be obtained as follows
from zinc that has been extracted from indium-bearing
blendes. The crude metal is neady dissolved in hydro-
chloric or nitric acid, and the solution is allowed to stand
twenty-four hours with the undissolved metal. A spongy
mass, consisting of the indium together with lead, copper,
cadmium, tin, arsenic, and iron, collects upon the residual
zinc. This mass is washed with water containing some
sulphuric acid ; it is then dissolved in nitric acid and evapo-
rated with sulphuric acid until all the nitric acid is removed.
By this process the lead is precipitated, and it may be
removed by filtration. The solution that remains is treated
with ammonium hydroxide in excess, and the hydroxides
of iron and indium are filtered off and dissolved in a small
amount of hydrochloric acid. This solution is treated
with an excess of acid sodium sulphite and boiled. In-
dium is precipitated as the basic sulphite (In3(S03)3 • In2(0H)e
+ 5H,0).

. The Element. A. Preparation. Elementary indium
may be obtained (i) by heating the oxide with carbon
or in a current of hydrogen; (2) by heating the oxide
vsdth sodium under a layer of dry sodium chloride ; (3) by
treating the salts with zinc.

B. Properties. Indium is a soft white metal, less vola-

f4- THE RARER ELEMENTS.

tile than cadmium and zinc. It melts at 174° C. At'
ordinary temperatures it is very stable in the air, but when 1
heated it ignites and bums with a violet flame to the ,
oxide. It does not decompose boiling water. It dissolves I
easily in hydrochloric, nitric, and sulphuric acids. Its j
specific gravity is given at from 7,1 to 7.4.

Compounds. A. Typical forms. The following com-
pounds of indium are known:

Oxides InO ln,0.

Hydroxide In(OH),

Chlorides InCl InCl, InCl,

Indium - hydrochloric

acid HjInCl,

Bromide l"l^''a

Iodide Inl,

Nitrate In,(N0,)a + 9H,0

Sulphate In,(SO,),

Double sulphates .... In,(SOJ, ■ K,SO, + 24HJJ ;

In,{SO,),-(NHJ,SO,+
a4H,0

Sulphite In,(S0,),-In,(0H). + 5H,O j

Sulphide IhjS,

Sulpho salts K,In,S, ; NaJn,S,

B, Characteristics. Indium resembles aluminum in 1
forming alums with potassium and ammonium sulphates, j
and in having a hydroxide soluble in excess of potassium I
or sodium hydroxide. It resembles zinc in forming a I
sulphide with hydrogen sulphide, but in the case of indium J
this salt is yellow. Indium monoxide is a dark powder l
slowly soluble in dilute acids. The sesquioxide is a yellow-,
ish-white powder easily soluble in warm acid. The di- '
chloride is formed directly by the imion of chlorine with the 1
metal, and is a white, crystalline mass. In water it sepa-fl
rates into the trichloride and the metal. By fusion o£j

GALUUM 75

the dichloride with elementary indium the monochloride
is formed, — ^a reddish-black, crystalline substance. The
trichloride is formed also by the action of chlorine in excess
upon the metal ; it is white like the dichloride and dissolves
in water with the evolution of heat. Solutions of indium
salts color the flame violet and give a characteristic flame
spectrum.

Estimation. Indium is generally determined as tho
oxide, (InjOj), obtained by ignition of the hydroxide, or as
the sulphide, (In^Sj), obtained by precipitation with hydro-
gen sulphide in the presence of sodium acetate.

Separation. The separation of this very rare element
from those elements with which it is usually associated
is treated tmder Extraction.

GALLIUM, Ga, 70.

Discovery. In 1875 Lecoq de Boisbaudran, who had
done much work with spectrum analysis, notified the
Academic des Sciences of his discovery of a new element
in a zinc-blende from the mine of Pierrefitte in the Pyre-
nees, and proposed for it the name Gallium (Compt. rend.
Lxxxi, 493; Chem. News xxxii, 159). The individu-
ality of the new body was distinctly indicated by the
spectroscope, but so small was the amount of it in the
possession of the discoverer that few of its reactions were
determined. Among the properties which he described,
however, were the following: the oxide, or perhaps a sub-
salt, was thrown down by metallic zinc in a solution con-
taining chlorides and sulphates; in a mixture containing
an excess of zinc chloride the new body was the first to
be precipitated by ammonia; in the presence of zinc it
was concentrated in the first sulphides deposited; the
spark spectrum of the concentrated chloride showed two
violet lines, one of them of considerable brilliance.

THE RARER ELEMENTS.

OccurreDce. Gallium is found combined, in very stna]
amounts, in certain minerals, chiefly zinc -blendes from
Bensberg on the Rhine, Pierrefitte, and other localitiea
It has been detected in some American zinc-blendes (Chem
Ztg. (1880), 443). The Bensberg sphalerite, one of th(
richest sources, contains 0.016 grm. per kilo.

Hartley and Ramage obtained the following interestinj
results by means of the spectroscope (Jour. London Cliem
Soc. (1897), 533, 547) : the presence of gallium was indicate(
in thirty-five out of ninety -one iron ores examined ; ■
the magnetites, seven in number; in all the aluminiia
ores, fifteen in number, mostly kaolin and bauxite; i
four out of twelve manganese ores; and in twelve out (
fourteen zinc-blendes.

Extraction. Salts of gallium are obtained by the fo)
lowing process : The mineral is dissolved in aqua regia ant
the excess of acid expelled by boiling. When the solution ij
cold, pure zinc is added, which precipitates the antimonjr
arsenic, bismuth, coyper, cadmium, gold, lead, mercury
silver, tin, selenium, tellurium, and indium. These
filtered off while there is stdl some evolution of hydrogen,
and the filtrate is boiled from six to twenty-four hovai
-with metallic zinc. Gallium is precipitated as a basii
salt, together with salts of aluminum, iron, zinc, etc. T
obtain the gallium salt in a more nearly pure conditio!
»;,the precipitate is dissolved in hydrochloric acid, the solu
tion is treated with hydrogen sulphide, and after filtra
tion and the removal of the excess of hydrogen sulphide
by boihng, sodium carbonate is added in small portions.
The gallium salt is the first to be precipitated, and the pre-
cipitates are collected as long as they show the galliumfl
lines in the spark spectrum. These precipitates are diai
solved in sulphuric acid and the solution is diluted large^
with water and boiled. The basic sulphate of galHu
■which is thus thrown down is dissolved in sulphuric £

GALLIUM. 77

and potassium hydroxide is added in excess. Iron if
present is removed at this point by filtration and the
gaUitim oxide is then precipitated from the filtrate by
carbon dioxide.

The Element. A. Preparation, Gallium in the elemen-
tary condition has been obtained by subjecting an alkaline
solution of the oxide to electrolysis.

B. Properties. A gray, lustrous metal, showing green-
ish-blue lights on reflecting surfaces, gallium is malleable
and fairly hard. Its fusing point, 30.15° C, is so low
that it melts readily from the warmth of the hand. In
water, and in air at ordinary temperatures, it is imchanged;
when heated in air or oxygen it is oxidized only superfi-
cially. It combines rapidly with chlorine, more slowly with
bromine, and not at all with iodine imless heat is applied.
Gallitun is soluble in hydrochloric and warm nitric acids,
and somewhat soluble in potash and ammonia solutions.
It alloys easily with aluminum, and these alloys decompose
cold water rapidly. Its specific gravity is 6.

Compounds. A. Typical forms. The following com-
potmds of gallium are known :

Oxides GaO? Ga^O,

Hydroxide Ga(OH),?

Chlorides GaCl^ GaCl,

Bromide GaBr,

Iodide Gal,

Nitrate Ga^CNOj^e

Sulphate Ga^CSOJ,

Double sulphate Ga^CSOJ, • (NHJ^SO, + 24H2O

B. Characteristics. The compounds of gallium resem-
ble those of aluminum and indium in forming alums and
in having a hydroxide soluble in excess of sodium or
potassium " hydroxide. The salts are colorless, and in
dilute solutions tend, on being heated, to become basic

THE RARER ELEMENTS.

and separate from the solution. The oxide (GajO,) Is i
soluble in acids and alkalies after ignition.

Estimation. Gallium is usually weighed as the oxide j
(Ga,OJ.

Separation.* Vid. Extraction.

THALLIUM, Tl, 204.1.

DiBCOTery. Some years previous to 1861 Crookes had
been engaged in the extraction of selenium from a selen-
iferotis deposit which he had obtained from the stdphuric-
acid manufactory at Tilkerode in the Hartz Mountains.
Some residues, left after the purification of the selenium,
and supposed to contain tellurium, were set aside and
not examined until r86i, when, needing tellurium, Crookes
vainly tried to isolate it by various chemical methods.
At length he resorted to spectrum analysis and tested
some of the residue in the flame. The spectrum of selen-
ium appeared, and as it was fading, and he was looking for
evidence of tellurium, a new bright-green line flashed into
view. The element whose presence was thus indicated
received the name Thallium, from the Greek daXKos, or
the Latin ihallus, a budding twig (Chem. News iii, 194).

About the same time Lamy announced the discovery
of the same element (Ann. Chim. Phys. [3] lxvii, 385),
but after much discussion and the presentation of much
evidence on both sides it was declared that Crookes had
the priority of discovery.

Occurrence. Thallium occurs in certain very rara
minerals :

Crookesite, (Cu,Tl,Ag)jSe, contains 16-19% Tl
Lorandite, TlAsS,, " 59-60% Tl

I

* For a detailed study of the separation of galliut
I,ecoq de Boisbaudran, CompL rend, xciv-xcvin.

, see many articles 1^ 1

It is found also in very small quantities in berzelianite,
(CujSe) ; in some zinc-blendes and copper pyrites; in iron
pyrites from Theux, NamuT, Philippevillc.Alais, and Nantes;
in lepidolite from Mahren; and in mica from Zinnwald.
It has been detected, together with caesium, rubidium, and
potassium, in the mineral waters of Natiheim and Orb.
Its presence in the flue-dust from some iron furnaces and
sulphuric -acid works, as well as in some crude sulphuric
and hydrochloric acids, may be traced to its presence in
the pyrites used.

Extraction. Thallium salts may be extracted by the
following methods:

(i) From miiierals. The finely powdered mineral is dis-
solved in aqua regia. The solution is evaporated with
sulphuric acid until the free acid has been removed ; it is
then diluted abundantly with water, neutralized with
sodium carbonate, and treated with potassium cyanide
in excess. This precipitates the bismuth and lead, which
are filtered off. The filtrate is treated with hydrogen
sulphide, which precipitates the cadmium, mercury, and
thallium as the sulphides. Very dilute sulphuric acid
dissolves the thalHum sulphide, leaving the cadmium and
mercury sulphides undissolved (Crookes).

(2) From flue-dust. The material is treated with an
equal weight of boiling water in a large wooden tub, and is
allowed to stand twenty- four hours. The liquid is si-j
phoned off and is precipitated with hydrochloric acid.*!
The crude chloride thus obtained is treated with an equal,
weight of sulphuric acid, and heated to expel the hydro-
chloric acid and the greater part of the excess of sulphuric.
The sulphate obtained is dissolved in water, the solution
is neutralized with chalk and filtered. By the addition
of hydrochloric acid to the filtrate, nearly pure thalloua
chloride is precipitated (Chem. News vni, 159). J

* Three tons of dust gave sxty-dgfat pounds of crude UiaUous chloiide, 1

I

THyfLLIUM. 8l,

Arseniates Tl^sO, 'nAsO,+ 3H,0

Cyanides TICN TI(CN}, ■ TICN

Sulphocyanide TISCN

Ferrocyanide TUFe(CN),+ iH,0

SiUpofluoride Tl^iF.

Chromates Tl^rO, ; T l^r.O,

Cbloropktinate . , . Tl.PtCl,

Molybdate Tl,MoO,

Timgstate T1,W0,

"Vanadates Tl.VO.; T1.V,0,; TIVO,

*B. Characteristics. Thallium compounds are known
an two conditions of oxidation, the thaUous, {T1,0), and
the, thaUic, (TI3O,) . The lower condition is the more stable ;
consequently the thallous compounds 'are the more numer-
ous and the better known. When the metal is allowed
»to oxidize in the air it forms the thallous oxide, but when it
is melted in an atmosphere of oxygen, thallic oxide is ob-
tained. ThaUic chloride, bromide, and iodide may be
formed by treating the corresponding thallous salts with
an excess of chlorine, bromine, and iodine, respectively.
In general, the thallous salts may be oxidized to the thalUc
form by strong oxidizing agents, such as potassium per-
manganate, lead dioxide, barium dioxide, etc. Thallium
in the lower condition resembles the alkalies potassium,
CEesium, and rubidium in having a soluble hydroxide, car-
bonate, and sulphate, and an insoluble chloroplatinate ;
also in forming alums. It resembles lead in forming an
insoluble sulphide and chromate, and in having halogen
salts soluble in hot water. The thallous salts are color-
less when the base is combined with a colorless acid. The
sulphide is brownish black. The thallic salts are in general
unstable, and on being heated with water tend to precipitate
the oxide {T]jO,-H,0). They may be easily reduced to
the lower condition by the action of reducing agents. They
may be formed by the careful treatment of thallic oxide
k with acids, as well as by the action of strong oxidizing
^nts upon the thallous salts. Solutions of thallium

8a THE RARER ELEMENTS.

salts in either condition of oxidation give to the flame a
characteristic green color.

EEtimation.* A . Gravimetric. Thallium is generally
weighed in the thallous condition (i) as the chloroplati-
nate, (TljPtClfl), after precipitation by chloroplatinic acid
(Crookes, Select Methods, Second Edition, 380); (2) as the
iodide (Til), after precipitation by potassium iodide
(Werther, Zeitsch. anal. Chem. 111, i, and J. B. (1864), 712;
Long, Zeitsch. anal. Chem. xxx, 34a}; {3) as the chro-
raate (TljCrOJ, after precipitation in alkaline solution by
potassium chromate (Browning and Hutchins, Amer.
Jour. Sci. [4] vm, 460) ; (4) as the sulphate (TljSO^), after
evaporation of appropriate salts with sulphuric acid in ex-
cess and ignition at low red heat, or as the acid sulphate,
(TIHSOJ, obtained by substituting for ignition heating at
22o''-24o°C. (Browning, Amer. Jour. Sci. [4] ix, 137).

B. Vohiifietric. Thallium is estimated volumetric-
ally (i) by the oxidation of thallous salts with perman-
ganate (Crookes, Select Methods, Second Edition, 381);
(2) by the action of potassium iodide upon thalUc salts,
as shown in the following equation (Thomas, Compt. rend.
cxxxiv, 655): T1C1,+ 3KI=T1I+3KC!, + I,.

Separatton.f In the more stable thallous condition, to
which thallic salts may readily be reduced, thallium may
be separated as follows; from the metals which give
precipitates with hydrogen sulphide in acid (but not acetic)
solution, by hydrogen sulphide; from elements which
form insoluble hydroxides with the alkali hydroxides, by
these reagents; and from the alkalies and alkali earths,
by ammonium sulphide.

•See also Hebberling, Liebig Annal. cxxxv, 207; Phipsoo, Compt.
rend, lxxvui, 563; Neumann, Liebig Anna! ccxijv, 349; Feit, Zeitsch,
anal. Chem. xxviii, 314; Carnot, Compt. rend. Cix, 177; Sponholz, Zeitsch.
anaL Chem, xxxi, 519; Thomas, Compt. rend, ckxx, 1316; Marshall,
Jour. Soc Chem. Ind. Xix, 994.

t See Crookes, Select Methods, Second Edition, 382-3S6.

\

EXPERIMENTAL IVORK ON THALLIUM.

EXPERIMENTAL WORK ON THALLIUM.

Experiment 73. Extraction of thallium salts from flue'
dust. The method described under Extraction may be
followed.

Experiment 74. Precipitation of thallous chloride, bro-
mide, and iodide (TlCl; TlBr; Til), (a) To a solution of
a thallous salt add hydrochloric acid or a chloride in solu-
tion. Note the solvent action of boiling water. Try
the effect of cooling the hot solution.

(6) Repeat the experiment, using potassium bromide
as the precipitant.

(c) Try similarly potassium iodide.

Experiment 75. Precipitation of thallium ckloroplati-
■nate (Tl,PtCl,). To a solution of a thallous salt add a
few drops of a solution of chloroplatinic acid.

Experiment 76. Precipitation of thallous chromaie-
(TljCrOJ. To a solution of a thallous salt add some potas-
^um chromate in solution. Try the action of acids upon
the precipitate.

Experiment 77. Precipitation of iliallous sulphide (TI,S),
(a) Through a solution of a thallous salt acidified with.
dilute sulphuric acid pass hydrogen sulphide. Note the
absence of precipitation. Divide the solution, and to one
part add ammonium acetate and to the other ammonium
hydroxide.

(&) Try the action of ammonium sulphide upon a thal-
lous salt in solution.

Experiment 78. Oxidation of thallous salts, (a) To a
solution of a thallous salt acidified with sulphuric acid add
gradually a little potassium permanganate. Note the
disappearance of the color of the permanganate.

(b) To a solution of a thallous salt add bromine water
until the color of the bromine ceases to fade. To one
portion add a few drops of a solution of a chloride or bro-

THE RARER ELEMENTS.

mide. Note the absence of precipitation. To another
portion add sodium or potassium hydroxide. Note the
precipitation of brown thallic hydroxide, (Tl,0,-HjO).

Experiment 79. Reduction of a Uiallic salt. To a solution
of a thalhc salt formed, for example, as in Experiment
78 (b) add stannous chloride. Note the precipitation
of thallous chloride, (TlCl).

Experiment 80. Flame and spectroscopic tests for thal-
lium salts, (a) Dip the end of a platinum wire into a
solution of a thallium salt and hold it in the flame of a
Bunsen burner. Note the green color.

(fc) Examine spectroscopically the flame colored by
a solution of a thallium salt. Observe the green line.

Experiment 81. Negative tests of thallous salts. Note
that siilphuric acid and the alkali hydroxides and car-
bonates give no precipitate with solutions of thallous salts.

VAlTADItlM, V, 51.2.

Discovery. As early as 1801 Del Rio announced the
" discovery of a new metal in a lead ore from Zimapan,
Mexico, He named it Erythronium (efivUpoe. red), be-
cause its salts became red when heated with acids
(Annal. der Phys. u. Chem. Lxxi, 7). Fourteen years later
Collet Descotils examined the supposed metal and pro-
nounced it an impure oxide of chromium,^ — a conclusion
that Del Rio himself came to accept (Ann. de Chim. liii,
268).

In 1830 Sef Strom found an unknown metal in an iron
ore from Taberg, Sweden. He proposed for it the name
Vanadium, from Vanadis, the Scandinavian goddess more
commonly known as Freia (Amer. Jour. Sci. [i] xx, 386).
Almost immediately Wohler showed the identity of vana-
dium with the metal described by Del Rio (Pogg. AnnaL
XXI. 49)-

I

VANADIUM. 85

Occtirrence. Vanadiiim is found qtiite widely distrib-
uted, but always in combination, and in very small quan-
tities:

Contains
V3O5.

Vanadimte, (PbCl)Pb,(V0,)3 8-21%

Descloizite, (Pb,Zn)2(0H)V0, 20-22%

Cuprodescloizite, (Pb,Zn,Cu)2(0H)V0, 17-22%

Calciovolborthite, (Cu,Ca)3(0H)V0, 37-39%

Camptite, Kfi'2Vfi^'Yfi^'i^Jd 19-20%

Brackebuschite, formula doubtful 24-25%

Psittacinite, formula doubtful 17-26%

Volborthite, ** '' 14-15%

Pucherite, BiVO^ 22-27%

Roscoelite, silicate, formula doubtful 21-29%

Ardennite, * * * * * * traces - 9%

Vanadium has been detected also in some copper, lead,
and iron ores, in certain clays and basalts, and sometimes
in soda ash and phosphate of soda.

Extraction. Vanadium salts may be extracted from
mineral sources by the following methods:

(i) The mineral is fused with potassiimi nitrate, and
the potassitim vanadate thus formed is extracted with water.
By the addition of a soluble lead or barium salt to the
solution the lead or barium vanadate is precipitated. This
insoluble vanadate is decomposed by means of sulphuric
acid, and the baritim or lead sulphate is filtered off. By
saturation of the filtrate with ammonium chloride the
ammonium vanadate is precipitated.

(2) The finely groimd mineral is decomposed by nitric
acid {vid. Experiment 82).

The Element. A, Preparation, Elementary vanadium
may be prepared by long heating of the dichloride in a ciir-
rent of hydrogen.

86 THE RARER ELEMENTS.

B. Properties. Vanadium is a non- magnetic, light-
gray powder, somewhat crystalline in appearance. It
oxidizes slowly in the air at ordinary temperatures, but
more rapidly when heated, going through various degrees
of oxidation and showing a characteristic color for each
oxide,— brown (V,0) , gray ( V,OJ , black ( V^O J , blue (Vfi,) .
and red (VjOa). Upon the application of heat vanadium
imites with chlorine, forming the chloride VCl,; at a red
heat it combines with nitrogen, giving the nitride VN. It
is insoluble in hydrochloric and dilute sulphuric acids,
and soluble in nitric, hydrofluoric, and concentrated sul-
phuric acids. It is not attacked byalkaUne solutions, but
with melted alkalies forms the alkali vanadates, with the
evolution of hydrogen. The specific gravity of vanadiiun
is 5-5-

Compounds. A. Typical forms. The following may
be considered typical compounds of vanadium;

Oxides V,0 V,0, V,0, Vf>, VA

Chlorides VCl, VCl, VClj

Oxychlorides VOCl VOCl,

Broinide VBrj

Oxybromides VODr, VOBr,

Fluorides V,F,+ 6HjO VF,

Double fluorides. . V,F, with KF, CoF„ NiF„ etc.

Sulphides V,S, V,S, V ^O,

V,Ss

Sulpho salts Na,VS,0

(NHJ.VS,, etc

Sulphate V,0i(SOJ,

Nitrides VN VN,

Vanadates, ortho, RjVO,

pyfo. R,VA

meta, rVO,

complex. V,0, with P,0,. MoO,, W0„ SiO„ AsO„ etc.

B. Characteristics. The vanadium compounds are
known in five conditions of oxidation, represented by the
five oxides. Of these conditions the highest is the most

I

VANADIUM. 87

Stable and is known in the largest nnmber of salts, the

vanadates. Vanadic pentoxide is reddish yellow in color,

and, like phosphoric pentoxide, it dissolves readily in the

alkali hydroxides and carbonates. The alkali vanadates

I
thus formed are of the ortho, pyro, and meta types, (R,VO^ ;
I I

RVjO^; RVOj). The vanadates are generally pale yellow

in color. They are soluble in the stronger acids and with
the exception of the alkali vanadates insoluble in water.
Vanadic acid is easily reduced by reducing agents to the
tetroxide condition, when the solution becomes blue. More
powerful reducing agents carry the reduction further, to
the trioxide, or even the dioxide condition, but only long-
continued heating in a ctirrent of hydrogen brings about
the reduction to the monoxide and the element.

Hydrogen sulphide, acting upon vanadic acid, reduces
it to the tetroxide condition or even below, with a sepa-
ration of sulphur. Ammonium sulphide gives the dark-
brown solution of a sulpho salt, ((NHJ^SjVO?), and this
solution, when acidified, gives a brown oxysulphide (V2S5O,).
Vanaditim resembles arsenic, phosphorus, and nitrogen,
both in the chemical structure of its compounds and in
their behavior toward reagents.

Estimation,* A. Gravimetric, Vanadium is usually
weighed as the pentoxide, '(V^Og), obtained (i) by precipi-
tation of lead or barium '^nadate, treatment with sulphuric
acid, filtration, evaporatioh'of the filtrate, and ignition; (2)
by precipitation of merctiry vanadate and ignition, the
pentoxide being left ; or (3) by precipitation of the ammo-
nium salt by ammonium chloride and ignition (Berzelius,
Pogg. Annal. xxii, 54; Gibbs, Amer. Chem. Jour, v, 371;
Gooch and Gilbert, Amer. Jour. Sci. [4] xiv, 205).

* See Die analjrtische Chemie des Vanadins, V. von Klecki, pub. by Leo-
pold Voss, Hamburg, 1894.

88

THE RARER ELEMENTS.

B. Volumetric. Vanadium may be estimated volu- ^
metrically (i) by reduction from the condition of the pent-
oxide to that of the tetroxide by sulphur dioxide, and re-
oxidation by pennanganate {Hillebrand, Jour. Amer. Chem.
Soc. XX, 461); (2) by effecting the reduction by boiling
with hydrochloric acid or with potassium bromide or iodide
in acid solution, according to the typical equation VjOj +
2HCl-V,0, + HjO+Cl3. The chlorine, bromine, or iodine
may be distilled, and determined by suitable means in the
distillate (Holverscheit, Dissertation, Berlin, 1890; Fried-
heim, Ber. Dtsch. chem. Ges. xxviii, 2067; Gibbs, Proc.
Amer. Acad, x, 250; Gooch and Stookey, Amer. Jour. Sci.
[4] XIV, 369; Curtis, Amer. Jour. Sci. [4] xvi), or the
residue after boiling may be rendered alkaline by potas-
sium bicarbonate, and reoxidation effected by standard
iodine solution (Browning, Amer. Jour. Sci. [4] 11, 185);
(3) or the reduction may be accomplished by boiling with
tartaric, oxalic, or citric acid, and reoxidation effected as
outlined above (Browning, 2^!tsch, anorg. Chem. vii, 158,
and Amer. Jour. Sci. [4] 11, 355).

Separation. Vanadium may be separated from the
majority of the metallic bases (i) by fusion of material
containing it with sodium carbonate and potassium nitrate
and extmction with water, vanaditun dissolving as sodium
vanadate; or (2) by treatm^if^jf a solution containing
a vanadate with ammonium '^fefomde in excess, vanadium
remaining in solution as a sulpEo''salt.

From arsenic vanadium maybe separated (i) by treat-
ment with hydrogen sulphide, after reduction by means
of sulphur dioxide, the arsenic being precipitated as the
sulphide ASjS,; (2) by heating the sulphides of vanadium,
and arsenic in a current of hydrochloric -acid gas at i5o°C.,
the arsenic forming a volatile compound (Field and Smith,
Jour. Amer. Chem. Soc. xviii, 1051).

From phosphorus vanadiimi may be separated by re-

EXPERIMENTAL IVORK ON VANADIUM. 89

duction of vanadic acid by means of sulphur dioxide, and
precipitation of the phosphorus as phosphomolybdate.

From molybdenum the separation may be accomplished
by the action of hydrogen sulphide upon a solution of vana-
dic and molybdic acids under pressure, — ^molybdenum sul-
phide being precipitated, — or by the action of ammonium
chloride in excess upon a solution containing an alkali
vanadate and molybdate, — ammonium metavanadate being
precipitated (Gibbs, Amer. Chem. Jour, v, 371).

From timgsten vanadium may be separated by the
anunonium chloride method {vid. Separation from molyb-
dentun, above) (Gibbs, Amer. Chem. Jour, v, 379).

EXPERIMENTAL WORK ON VANADIUM.

Experiment 82. Extraction of vanadic pentoxide from
vanadinite, ((PbCl)Pb^(V0^)5). Treat a few grams of the
finely powdered mineral with nitric acid, heat until nothing
further dissolves, dilate and filter. Remove the lead from
the filtrate by hydrogen sulphide, filter again, and evaporate
the filtrate to dryness, adding a little nitric acid after the
hydrogen sulphide has boiled out, to insure the oxidation of
the vanaditun. Ignite the residue.

Experiment 83. Formation of insoluble vanadates of

n Tx

lead, silver, and barium, (RjCVOJj, ortho; or R(V03)2, meta).
(a) To a solution of an alkali vanadate (ortho or meta)
add a solution of lead acetate.

(6) Repeat the experiment, substituting silver nitrate
for lead acetate. Note the flocky character of the pre-
cipitate when shaken.

{c) Use barium chloride as the precipitant.

{d) Try the action of nitric and acetic acids upon these
salts.

90 THE R/1RER ELEMENTS.

Experiment S4. Formation of vanadium pentoxide, (V,Oj),
from ammonium vanadate. Evaporate a solution of am-
monium vanadate to dryness and ignite. Note the cry^als
of the pentoxide.

Experiment 85. Precipitation of vanadium oxysulphidg^
(VjSjO,). (o) To a solution of an alkali vanadate add
ammonium sulphide. Note the darkening in color
((NH,),S,VO?). Acidify the solution with hydrochloric
acid. Note the precipitation of the oxysulphide,

(b) Note that hydrogen sulphide in an acid solutii
precipitates sulphur and leaves a blue solution (VjOJ,

Experiment 86. Reduction of vanadic acid, (VjO,),
(a) To a solution of an alkali vanadate add a crystal of
tartaric acid and boil. Note the yellow-red color of the
vanadic acid when the tartaric acid is first added,
the change to blue (V^O,) produced on boiling.

(fe) Neutralize the blue solution obtained in (a) with
sodiiun or potassium bicarbonate, and add a solution of
iodine in potassium iodide until, after the liquid has stood
for a few moments, the color of the iodine remains. Bleach
the excess of iodine with an alkaUne solution of arseniotis
oxide. Note that the blue color has disappeared and the
vanadium is in the condition of the pentoxide (VjOs).

(c) Try the action of other reducing agents upon vanadic
acid, e.g. oxalic acid, hydrochloric acid, stannous chloride,
zinc and hydrochloric acid, etc. Note that the zinc
hydrochloric acid carry the reduction below the tetroxic
condition (VjO^).

Experiment 87. Delicate tests for vanadium, (a) Acidify
a solution of an alkah vanadate and add hydrogen dioxide.
Note the red color (Maillard).

(b) Bring a few drops of the vanadium solution into
contact with a drop of strong sulphuric acid to which a
crystal of strychnine sulphate has been added Notaj
the color, changing from violet to rose.

m

or
He

tioa^l
,00.

,1 of ■
- the

with^'
1 of
:ood
iach
iotis
the
i).

adic
:ide, |

MOLYBDENUM. 9^

Experiment 88. Borax-bead tests for vanadium. Ftise
a little ammonium vanadate into a borax bead and test
the action of the reducing and oxidizing flames upon it.

MOLYBDENXTM, Mo, 96.

Discovery. The name Molybdena, derived from pi6\v/36os,
lead, was originally applied to a variety of substances con-
taining le^. Later the term was used to designate only
graphite -and a mineral sulphide of molybdenum which is
very similar in appearance to graphite, and which was
confused with it. In 1 778 Scheele, in his treatise on molyb-
dena (Kong. Vet. Acad. Handl. (1778), 247), showed that
it differs from plumbago, or graphite, in that on being
heated with nitric acid it yields a peculiar white earth,
which he proved to be an acid-forming oxide. This he called
* ' acidum molybdenae, ' ' and he supposed the mineral to be
a compoimd of this oxide with sulphur. In 1790 Hjelm
(ibid. (1790), 50; Ann. de Chim. iv, 17) isolated the ele-
ment.

Occurrence. Molybdenum occurs in combination in
minerals which are somewhat widely diffused, though
found in small amoimts:

Contains
Mo

Molybdite, M0O3 66-67%

Molybdenite, MoS^ 60%

PoweUite, Ca(Mo,W)0, 58-59%*

Wulfenite, PbMoO, 37-40%*

Belonesite, MgMoO^? 78-79%*

Scheelite, CaWO, traces- 8%*

Extraction. Molybdenum salts are usually obtained
from molybdenite, the most abtmdant ore, though some-

* MoO,.

THE RARER ELEMENTS.

times from other minerals. The following processes will
illustrate the methods employed.

(i) From inoiybdemte. The mineral is roasted until
sulphur dioxide is no longer given off and the residue is
yellow when hot and white when cold. T,:!s residue is
dissolved in dilute ammonium hydroxide, and the solution
is evaporated to crystallization. Heat drives off the
ammonia from the crystals and leaves the trioxide of
molybdenum.

(2) From molybdenite. The mineral is treated with
nitric acid {vid. Experiment 89),

(3) From wulfenite. The mineral is fused with potas-
sium polysulphide. Upon extraction with water the lead
remains insoluble, as the sulphide, and the molybdenum
goes into solution as the sulpho salt. The filtrate is acidi-
fied with sulphuric acid, and the sulphide of molybdenum
is precipitated (Wittstein).

The Element. A. Preparation. Elementary molybde-
num may be prepared (i) by passing dry hydrogen over
either the trioxide or the ammonium salt at red heat,
and (2) by reducing the chlorides with hydrogen.

B. Properties. Molybdenum is a gray metallic powder,
which is unchanged in the air at ordinary temperatures, but
which, when heated, passes gradually into the trioxide.
It is insoluble in hydrochloric, hydrofluoric, and dilute
sulphuric acids, but soluble in nitric and concentrated
sulphuric acids, in aqua regia, in chlorine water, and in
melted potassium hydroxide, and potassiimi nitrate. Its
specific gravity is 8.6.

Compounds, A . Typical forms. The following are typ-
ical compounds of molybdenum:

Oxides. MoO Mo^, MoO, Mo,Oi, MoiO, MoO,

Chlorides MoCl, MoCl, MoCl. Mod,

Oxychlorides, MoOCI,

MoO^,
Bromides MoBr, MoBr, MoBr,

MOLYBDENUM 93

Oxybromide.. MoO}Br}

Oxyiodide.... MoOjI

Oxyfluorides . MoOF^ • 2KF

• +HjO

MoOjFj.KF
rV +H,0

Sulphides.... MoSi MoS8;MoS4

I
Sulpho salt . . . RjMoS*

I
Molybdates, many salts of the type R2M0O4, as K2M0O4; CaMoO*; ZnMo04;

Ag2Mo04; etc.

Molybdenum trioxide combines with phosphoric pent-
oxide in the following proportions : PjOg : M0O3 : : i : 24,
1:22, 1:20, 1 : 18, 1 : 16, 1 : 15, 1:5, as 2K2HP04-24Mo03 +
3H2O; 2(NH,)3PO,-i6Mo03 + i4H20; etc. It combines
with arsenic pentoxide as follows: ASjOgiMoOg: :i :2o,
1:18, 1:16, 1:6, 1:2, as As205-2oMo03 + 2 7H20;
ioNH3-'As205-i6Mo03 + i4H20; etc.

B, Characteristics, The molybdenum compounds are
known in various conditions of oxidation {vid. Typical
Forms), of which the highest, (M0O3), is the most stable and
comprises the largest number of salts. The trioxide is
white to pale yellow, and dissolves in potassium, sodium,
and ammonium hydroxides, forming the molybdates.
When strong reducing agents, such as zinc and hydro-
chloric acid, act upon acid solutions of molybdates, the
reduction is said to go as far as the oxide M05O7, the solu-
tion passing through the colors of the various oxides,
violet, blue, and black. The oxide M05O7, however, is
very sensitive to oxidation, for it is changed in the air to
the sesquioxide (M02O3) as soon as the reducing action has
ceased. Acid solutions of the lower oxides give, on treatment
with the alkali hydroxides, the corresponding hydroxides of
molybdenum, M02O3 • 3H2O ; M0O2 • :3i;H20 ; etc. The sulphide
(MoSj) is obtained by treating a molybdate with ammonium
sulphide and acidifying. Its color is reddish brown.

Estimation. A, Gravimetric. Molybdenum is generally

THE RARER ELEMENTS.

weighed as the oxide (MoOj), obtained (i) by ignition of
ammonium molybdate; (z) by precipitation of mercury
molybdate and ignition; or (3) by precipitation of the
sulphide and conversion into the oxide by treatment with
nitric acid.

B. Volumetric. Soluble molybdates may be reduced
in acid solut'on by boiling with potassium iodide, and
the iodine thus liberated may be passed into potassium
iodide and estimated by standard thiosulphate, the amoimt
of molybdenum present being calculated from the equation
2MoO,+ 2HI =Mo,0, + I,+ Hp; or, after the iodine has
been removed by boiling, the residual solution may be
rendered alkaline by potassium bicarbonate and reoxidized
by standard iodine solution or potassium permanganate
(Mauro and Danesi, Zeitsch. anal. Chem. xx, 507; Pried-
hcim and Euler, Ber. Dtsch. chem, Ges. xxviii, 2066;
Gooch and Fairbanks, Amer. Jour. Sci. [4] 11, 156; Gooch
and Pulman, Amer. Jour. Sci. [4] xii, 449).

Separation. The general methods for the separation
of molybdenum from the metals and alkali earths are the
same as those described under Vanadium.

From arsenic and phosphorus, when present as arsenic
and phosphoric acids, molybdenum may be separated by
magnesium chloride mixture in ammoniacal solution,
ammonium-magnesium arseniate and phosphate being
precipitated (Gibbs, Amer. Chem. Jour, vii, 317; Gooch,
Amer. Chem. Jour, i, 412).

For the separation from vanadium, vid. Vanadium.

From tungsten molybdenum may be separated (i) by
the action of warm sulphuric acid of specific gravity 1.37
upon the oxides (MoO^ and WOj), molybdic acid dissolv-
ing (Ruegenberg and Smith, Jour. Amer. Chem. Soc.
XXII, 772}; (z) by heating the oxides with hydrochloric-
acid gas at 2SO°-2 7o° C, the molybdenum compound
(Mo0g-2HC1) being volatiUzcd (Pecliard, Compt. rend.

I

EXPERIMENTAL IVORK ON MOLYBDENUM. 95

cxiv, 173; Debray, ibid, xlvi, iioi); (3) by precipitation
of the sulphide of molybdenum by means of hydrogen
sulphide in the presence of tartaric acid (Rose, Handbuch
der anal. Chemie (sechste Auflage, 1871), 358).

EXPERIMENTAL WORK ON MOLYBDENUM.

Experiment 89. Extraction of molybdenum salts from
molybdenite, (M0S2). Heat 5 grm. of the finely powdered
mineral with nitric acid until the dark color has disap-
peared. Evaporate to dryness, Wash the residue in warm
dilute nitric acid, then in water, and dissolve it in am-
monium hydroxide. Filter, and evaporate the filtrate to
a small volume. Ammonium molybdate crystallizes out,
which may be converted into the trioxide by careful
ignition.

Experiment 90. Precipitation of the sulphides of molyb-
denum, (M0S2; M0S3). (^) Through a solution of am-
monium molybdate acidified with hydrochloric acid pass
hydrogen sulphide. Note the gradual change of color
of the solution, from red-brown to blue, and the partial
precipitation of the sulphide M0S2.

(6) To a solution of ammonium molybdate add am-
monium sulphide, or pass hydrogen sulphide through an
alkaline solution of a molybdate. Note the yellow-brown
color ((NH4)2MoS4, typical). Acidify the solution and
note the brown precipitate (M0S3).

Experiment 91. Precipitation of ammonium phospho-
molybdate (3(NHj20-P205-24(Mo03) -h2H20). To a solu-
tion of ammonium molybdate acidified with nitric acid
add a drop of a solution of sodium phosphate, and warm
gently. Note the yellow precipitate.

Experiment 92. Precipitation of the molybdates of
silver, lead, and barium, (AgjMoO^, PbMoO^, and BaMoO^,
typical). To separate solutions of ammonium molybdate,

THE RARER ELEMENTS.

neutral or faintly acid with acetic acid, add solutions of!
silver nitrate, lead acetate, and barium chloride respec-
tively. Note the solvent action of nitric acid upon the 1
precipitates.

Experiment 93. Reduction of molyhdic acid, (MoOj),
(a) Put a piece of metallic zinc into a solution of ammo-
nium molybdate and add hydrochloric acid until the action ]
starts. Note the change in color of the solution as the
reduction proceeds (reddish yellow, violet, bluish, black).
To a few drops of the solution after reduction add potas-
sium' or sodium hydroxide. Note the dark-brown pre-
cipitate of the lower hydroxides of molybdenum (Mo,{OH)fc .
etc.) mixed with the hydroxide of zinc.

(i) Try the reducing action of stannous chloride upon j
a molybdate in solution.

(c) To a dilute solution of a molybdate which has been I
treated with zinc and hydrochloric acid, add some potas-
sium sulphocyanide in solution. Note the red color. Try '
the effect of adding ether and shaking.

Experiment 94. Preparation of elementary molybde-
num from ammonium molybdate. Heat a few grams of
finely powdered ammonium molybdate until no further
test for ammonia is obtained when a piece of moistened
red litmus paper is held over the substance. Remove the
molybdic trioxide thus obtained to a Rose crucible and
heat for some time in a current of hydrogen. Note the 1
gray powder.

TDHGSTEN, W, 184.

Discovery. The minerals scheehte, formerly called I
timgsten (i.e. "heavy stone"), and wolframite have long!
been known, but until about the middle of the eighteenth ]
century they were regarded as tin ores. In 17S1 Scheele I
(Kong. Vet. Acad. Handl. (1781), 89) demonstrated that!
scheelite contained a peculiar acid which he named Tung-

TUNGSTEN. 97

Stic acid. Two years later the brothers D 'Elhujar showed
the presence of the same acid in wolframite.

Occurrence. Ttmgsten is fotmd combined in minerals
which are often associated with tin ores:

Contains
WO,.

Wolframite, (Fe,Mn)WO, 74-78%

Scheelite, CaWO, 71-80%

Hubnerite, MnWO, 73-77%

Cuprottmgstite, CuWO^ 56-57%

Cuproscheelite, (Ca,Cu)WO, .• 76-80%

PowelUte, Ca(Mo,W)0, 10-11%)

StolzitQ, PbWO, 51 circa

Raspite, PbWO, 49 "

Reinite, FeWO, 75-76%

Ttmgstite, WO, 100 circa

«

Extraction. Ttmgstic acid is usually extracted from
wolframite. Either of the processes here indicated may
be followed:

(i) 5 parts of the mineral are fused with 8.5 parts of
dry sodium carbonate and 1.5 parts of sodium nitrate.
On treatment of the fused mass with water, sodium tung-
state is dissolved, and after filtration timgstic acid is pre-
cipitated by hydrochloric acid.

(2) The mineral is decomposed by hydrochloric acid
(vid. Experiment 95).

The Element. A. Preparation, Elementary tungsten
may be obtained (i) by heating the acid in the presence
of hydrogen; (2) by heating the chloride (WCIq) in the
presence of hydrogen ; (3) by heating the acid with carbon ;
(4) by heating the nitride.

B. Properties. Ttmgsten is a very hard powder rang-
ing in color from gray to brownish black, resembling some-
times tin, sometimes iron. Although imchanged in the air

98 THE RARER ELEMENTS.

at ordinary temperattires, when heated in finely divided
condition it ignites and bums to the oxide (WO,). It
dissolves when heated with sulphuric, hydrochloric, and
nitric acids. It is attacked by dry chlorine at high temper-
atures; also by concentrated boiling potassium hydroxide,
with the formation of potassium tungstate. The specific
gravity of ttmgsten is from 16.5 to 19.1.

Compounds. A, Typical fornix. The following com-
poimds of tungsten may be considered typical :

Oxides* wo, WO,

Chlorides WCl, WCI4 WCU WCI,

Oxychlorides , WOCI4

W0,C1,

Bromides WBr, WBr,

Oxybromides WOBr*

WOjBr,

Iodide WI,

Double fluorides . . KF • WO,F+ H/) ZnF, • WO,F,+ idUfi ;

etc.

Sulphides WS, WS,

Sulpho salts R2WS4

R,WS,0,
R,WS0,

Tungstates, many salts of the types^ RjWOi (normal)

R1W4O1, (meta)
R^WyO,^ (para)

Timgstic trioxide (acid) combines with phosphoric
pentoxide, arsenic pentoxide, and siHcon dioxide in the
following proportions:

PjOg: WO3: : 1 : 22, 1 : 21, 1 : 20, 1 : 16, i : 12, i : 7.
ASjOg : WO,: : i : 16, i : 6, i : 3.
SiOji WO,: : 1 : 12, i : loi

B, Characteristics, The compounds of tungsten are
very similar to those of molybdenum, and are known

* Some authorities give three oxides between the dioxide and the trioxide,
viz., W2O5, WjOg, and W4OU.

\

TUNGSTEN. 99

in several conditions of oxidation (vid. Typical Forms), of
which the highest is the most stable. The trioxide, (WO,),
tmited with the bases, forms the largest number of salts,
the ttmgstates. When acted upon by reducing agents,
ttmgstic acid or trioxide may be reduced to the dioxide,
(WO2), the solution becoming blue, then brown. When
the solution of a ttmgstate is acidified, timgstic acid is
precipitated. Timgstic sulphide, (WS3), is obtained tmder
the same conditions as molybdenum sulphide, and is brown.
It dissolves in ammonium stdphide, forming a stdpho salt.

Estimation. Ttmgsten is ordinarily weighed as the oxide
(WO 3), obtained (i) by igniting ammonium ttmgstate; (2)
by decomposing the alkali tungstates with nitric acid,
evaporating to dryness, and extracting with water, — ^tung-
stic acid remaining undissolved; (3) by precipitating mer-
cury tungstate and driving off the mercury by means of
heat, leaving the acid or oxide ; (4) by boiling fused lead
tungstate with strong hydrochloric acid, — ^tungstic acid
being precipitated (Brearley, Chem. News lxxix, 64).

Separation. Ttmgsten may be separated from the me-
tallic bases and many other elements by the following
process : ftision with an alkali carbonate, extraction of the
alkali ttmgstate with water, acidification with nitric acid,
evaporation to dryness, and extraction with water, — ^ttmg-
stic acid remaining tindissolved.

For the separation of ttmgsten from molybdenum and
vanaditun, see those elements. From arsenic and phos-
phorus ttmgsten is separated by magnesium mixture
(Gk)och, Amer. Chem. Jour, i, 412; Gibbs, Amer. Chem.
Jour. VII, 337).

From tin the separation may be accomplished (i) by
ignition with ammonium chloride, tin chloride being vola-
tilized (Rammelsberg) ; (2) by fusion with potassium cyanide,
the tin being reduced to the metal and the ttmgsten being
converted into a soluble ttmgstate (Talbot).

^^

>>K^e\

THE RARER ELEMENTS.

EXPERIMENTAL WORK ON TUNGSTEN.

Experiment gg. Extraction of tungsiic acid from mo^
/ratMite((Fe,Mn)WO,). Treat j grm. of the finely powdered
mineral with about lo cm.' of a mixture of equal parts of
hydrochloric acid and water, and boil as long as any action
seems to take place. Decant the solution, add to the
residue about lo cm.' of a mixture of nitric and hydro-
chloric acids (aqua regia), and warm. Add more acid if
necessary, and continue this treatment until the residue is
yellow, then filter and wash. Warm the yellow mass with
ammonium hydroxide as long as any solvent action is
observed, and filter. Evaporate the filtrate to dryness
and ignite the ammonium tungstate to obtain tungstic
acid.

Experiment 96. Formation of sodium tungstate,
(Na,WO^, typical). Dissolve a little tungstic acid in a
solution of sodium carbonate.

Experiment 97. Precipitation of tungstic sulphide,
(WSj,), and formation of the sulpho salt ((NH,),WS.}, (o) To
a solution of sodium or ammonium tungstate add ammo-
nium sulphide, and acidify with hydrochloric acid.

(b) Try the action of hydrogen sulphide upon a soluble
tungstate.

(c) Try the action of ammonium sulphide upon tungstic
sulphide.

Experiment 98. Precipitation of tungstic acid, (WO,).
Acidify a concentrated solution of a tungstate with hydro-
chloric or nitric acid and boil.

Experiment 99. Precipitation of barium, lead, and silver
tungstales, (RjWO^, typical). To separate portions of a
solution of sodium tungstate acidified with acetic acid add
solutions of barium, lead, and silver salts respectively.

Experiment 100. Reduction of tungstic acid, (a) To
a solution of a tungstate (e.g. sodium tungstate) add a

URANIUM. loi

solution of stannous chloride. Acidify with hydrochloric
acid and warm gently.

Experiment loi. Salt of phosphorus bead tests. Make
a bead of microcosmic salt, and heat it in the oxidizing
and reducing flames with a small particle of tungstic acid.
Try the effect of a small amotmt of ferrous sulphate upon
the bead heated in the reducing flame.

URANIUM, U, 238.5.

Discovery. Klaproth, in the year 1789, discovered that
the mineral pitch-blende, supposed to be an ore of zinc,
iron, or ttmgsten, contained a ** half-metallic substance"
differing in its reactions from all three (Crell Annal. (1789)
III 387). This he named Uranium in honor of Herschel's
discovery of the planet Uranus in 1781. The body that
Klaproth obtained was really an oxide of uranium, as
P61igot showed in 1842, when he succeeded in isolating
the metal (Ann. de Chim. (1842) v, 5).

Occurrence. Uranium is found combined in a few min-
erals, most of them rare. Pitch-blende is the most abtm-
dant sotirce.

I/ramntfe(/>tte;t-6fenA?),UO,.U0,.PbO.N, etc., contains 75-85% (UOa+UOj)

Gi*wwite,(Pb,Ca)UgSiOi,.6HaO?, " 61-75% UO,

Thorogummite, UO,-3ThOj-3SiO,-6H,0, " 22-23% "

Maddntoshite, UO,- 3ThOa- 3810,. 3H,0, " 21-22% UOj

Uranophane, CaO • 2UO, • 2810, • 6H ,0, " 53-^7% UO,

i/ra«OJ/>Aaef»fe, (BiOjUA-aHaC '* 5^5^% "

Walpiirgite, Biio(UO,),(OH)^(AsOj4, *' 20-21% "

Camotite, K,0 • 2U A • V A • 3H A " 62-65% U A

Torbermte, CuCUOaPaOj • 8H A " 57-62% UO,

Zcmieritc,Cu(UO,),As,0,.8H,0, " 55-56% "

>liilaitite,Ca(UO,),P,0,.8HA " 55-62% "

Uianospinite, Ca(U02),As,0,.8b,0, " 59-6o% "

Uianocircite,Ba(UO,),PA-8H,0, " 56-57% '*

Jofaannite, sulphate, formula doubtful, " 67-68% '*

Uianopilite,Ca0.8UO,.2SO,-25H,0, " 77-78% "

Thorite, ThSiO*, " 1-10% "

THE RylRER ELEMENTS.

• Phosp&uranyUte, (UOJ,P,0, -611,0,
' TrOgerite, (UO^,As,Oj-i2H,0,

I Uranothallite, 3CaCOj.U(CO0,-ioHA
Liebigite, CaCO,-(UO,)CO,-2oH,0,
Voglite, complex carbonate,

Hatcheltolite, R(Nb,Ta),0,-HiO.

Fergusonite, R(Nb,Ta)0„
Sipylite, complex niobate,

Samarskite, R,R^(Nb,Ta),0^

Euxeaite, R(NbO,),-R,(TiOJ,-|H,0,
Polycrase, RCNbO,),-3R{TiOJ,-3H,0,

7^-77% t
63-64%

35-37% ^

36-38% U

37% U

-"%
"9%

Extraction. Uranium salts may be extracted from pitch-
tlende as follows;

(i) The mineral is decomposed with nitric acid, the
acid solution is evaporated to dryness, and the mass is
extracted with water. The residue, which consists largely
of lead sulphate, iron arseniate, and iron oxide, is filtered
off, and on evaporation of the solution impure nitrate of
uranium crystallizes out, which may be purified by re-
crystallization (P^ligot).

{2) The mineral is decomposed by aqua regia {vid.
Experiment 102).

The Element. A. Preparation. Metallic uranium may-
be obtained (i) by heating a mixture of the chloride UCl,
' with sodium and potassium chloride in a porcelain cru-
. cible stirrounded by powdered carbon contained in another
I crucible (P61igot) ; (2) by heating a mixture of uranium
L chloride, sodium chloride, and metallic sodium in a closed
[ iron crucible.

B. Properties. Uranium is a somewhat malleable white
I metal with much the appearance of nickel. Heated in
[ air or oxygen to a temperature of iso^-iyo^C. it bums

I

URANIUM. 103

to the oxide ; at ordinary temperatures the oxidation takes
place slowly. Uranium dissolves slowly in cold dilute sul-
phuric acid, and more rapidly upon the application of heat.
It is soluble in nitric and hydrochloric acids. It is attacked
by chlorine at 150° C. and by bromine at 240^0. The
caustic alkalies have no apparent action upon the element.
The specific gravity of uranium is 18.6.

Compounds. A, Typical forms. The following are typ-
ical compounds of tiranium:

Oxides * UO, U,08(U0,+

2UO,) UO,

Carbonates UO2CO, • 2K2CO,

U02COa-2(NH4),CO,

Chlorides. UCl, UCI4 UCl, UO2CI,

Bromides UBr, UBr* UBr, UOjBrj

lodate UOjaO,),

Fluorides UF* UOjF,

U02Fj-NaF,ctc
Sulphides. US UA US, UOS,

Sulphates. U(SOJrl" U0:S04+ aiHaO

4H,0
Nitrate UOjCNO,)^^ 6Hfi

Nitride UjN^

Ferrocyanides. . . . UFe(CN), (UO,),K,(FcCN,),

Phosphates, ortho. UOHPO4 (UOa),H^P04)4

pyro.. (UO),PA (UO,),PA

meta.. UO(POJ, U02(PO,)2

Arseniate. UO,H ASO4+ /^Hfi

Uranates^ of types RaUO*, RjU A. and R4UO,.

B. Characteristics, Uranium differs from vanadium,
molybdenum, and ttmgsten in manifesting less marked
acidic qualities. The chief classes of salts are the uranyl,
in which uranium shows its highest degree of oxvlixivm,
corresponding to the oxide UO, ('e.g. UOjCl^;, and the
uranous, of which the oxide UO^ is the tvfx; ^e.g. UCl^;.
The uianyl salts are the more stable and hf^Wzv known.
They may be reduced by zinc and hydrochloric add to

* Otber oxides less well known than those given above are of the follow*
ing fonns: UO, UjQ,* UA, and UO4.

I04

THE RARER ELEMENTS.

the lower condition. The iiranous salts are easily oxidized
to the higher form. The uranyl salts are, in general,
yellow, the uranous greenish. The two conditions of
oxidation may be ftirther distinguished by the following
reactions : the precipitate resulting from the action of
ammonium sulphide upon uranyl salts is reddish brown, —
upon uranous salts, light green ; the precipitate resulting
from the action of potassium ferrocyanide upon uranyl
salts is blood-red, — upon uranous salts yellowish green.

Uranates of the types RjUO, and RjU^Oj are formed by
the combination of the oxide UO, with the strong bases.

Estimation.* A, Gravimetric. Uranium may be
weighed (i) as urano-uranic oxide (U,Og), obtained by
precipitation of ammonium uranate by means of ammonia,
and ignition in air or oxygen; (a) as urano-uranic oxide,
precipitated electrolytically by a current of o.iS ampere
and 3 volts at a temperature of 70° C. (Smith and Wallace,
Jour. Amer. Chem. Soc. xx, 379; Smith and Kollock, ibid,
xxiii, 607); (3) as uranous oxide (UOJ, obtained by ig-
nition of urano-uranic oxide in a current of hydrogen;
C4) as the pyrophosphate ((UOJjPjO,), obtained by pre-
cipitation by means of ammonium phosphate in the pres-
ence of ammonium acetate, and ignition.

B. Volumetric. Uranium may be estimated volumet-
rically by reduction from the higher (UO,) to the lower
(UOj) condition of oxidation by means of zinc and sul-
phuric acid, and oxidation with permanganate, according
to the following formuke (Pulman, Amer. Jour. Sci, [4] xvi) :
(i) UO^SO, +Zn + 2H,S0,= ZnSO, -|- U(SO.), -\- aH,0 ;
(2) 2KMnO. + 5U(SO.)j + 2H,0=-

2KHSO, + 2 MnSO, -I- H,SO. -H 5 UO,SO..

Separation.* From the metals which precipitate sul-
phides with hydrogen sulphide in acid solution, uranium

• Vid. Kern, Jour. Amer. Chem. Soc. xxui, 685.

I

EXPERIMENTAL WORK ON URANIUM.

105

may be separated by hydrogen sulphide. From iron, ,
nickel, and other members of its owti group it may be
separated by ammonium sulphide in the presence of an
excess of sodium or ammonium carbonate, the uranium |
salt remaining in solution. From the alkalies and alkali ;
earths the separation may be accomplished by means of
ammoniiun sulphide in the presence of ammonium chloride,
uraniiun oxysulphide being precipitated.

I

I

EXPERIMENTAL WORK ON URANIUM.

Experiment 102. Extraction of uranium salts from pitch-
blende. Warm 5 grm. of pulverized pitch-blende with
aqua regia until the decomposition is complete, and remove
the excess of acid by evaporation. Extract with water and
boil the solution a few minutes with sulphurous acid to
reduce the arsenic acid. When the liquid is at about 60° C,
pass hydrogen sulphide through to the complete precipita-
tion of arsenic, copper, lead, bismuth, and tin. Filter,
oxidize the filtrate with nitric acid, and precipitate with
ammonium hydroxide. Treat the precipitate with hot
concentrated ammonium carbonate, filter, and allow the
filtrate to cool. The double carbonate of uranium and
ammonium will separate. A ftirther precipitate, of crude
ammoniiun uranate, may be obtained by boiling the mother-
liquor.

Experiment 103. Precipitation of sodium, potassium, '

or ammonium uranate, (R^UjOj, typical). To a solution
of a uranyl salt add sodium, potassium, or ammoniimi
hydroxide. Note the yellow color of the precipitate and
the- insolubility in excess of the reagent. Repeat the
experiment with tartaric acid present in the solution.

Experiment 104. Formation of the soluble double car-
bonates of uranium with sodium or potassium, and uranium J

io6

THE RARER ELEMENTS.

with ammonium, (UOjCOj-aRjCO,) ■ (a) To a solution
a uranyl salt add a solution of sodium or potassium ci
bonate, noting the first and the final effects. Try the
suit of boiling, and of adding sodium or potassium hydro:
ide to a separate portion of the clear solution.

{b) Try similarly the action of ammonium carbonate
upon a uranyl salt in solution. Note the ready solvent
action of an excess of the carbonate, and the precipitation
of ammonium uranate, {(NHJ^UjO,), on boiling.

(c) To a solution of a uranyl salt add hydrogen di-
oxide and potassitom or sodium carbonate. Note
cherry-red color (Aloy).

Experiment 105. Precipitation of uranyl ferrocyan;
((UO,)3K,{FeCoN J, or (UOj),FeC,N.). (a) To a very dilute
solution of a uranyl salt add a little potassium ferrocyanide
in solution. Note the red precipitate. This is a delicate
test for uranyl salts.

(b) Try similarly the action of potassiimi ferricyanic

Experiment 106. Precipitation of uranyl phospi
(UOjHPOJ. To a solution of a uranyl salt add a solution
of hydrogen disodium phosphate. Try the action of the
common acids upon the precipitate.

Experiment 107. Precipitation of uranyl sulpkt
{UO,S). (a) To a solution of a uranyl salt add ammonii
sulphide. Note the dark-brown color of the precipital
and the insolubility in excess of the reagent.

(fc) Try the action of hydrogen sulphide upon a uran'
salt.

Experiment 108. Reduction of uranyl salts, (a) To,
solution of a uranyl salt add zinc and sulphuric acid. Ni
the change of color from yellow to green.

(b) Bring about the reduction with magnesium
acid. Test the uranous salt in solution with potassii
ferrocyanide and with ammonium sulphide.

TELLURIUM.

107

TELLURIUM, Te, 127.6.

Discovery. Native telltirium, which is qtiite widely
distributed in small quantities, was a puzzle to the early
mineralogists. Because of its non-metallic properties and
its metallic luster it was known as aurum paradoxum and
metallum problematicum. In 1782 Muller von Reichen-
stein, after some careful work on this interesting substance,
suggested that a peculiar metal might be present. Acting
on the suggestion, Klaproth undertook an investigation,
and in 1798 he demonstrated that the ** metal* * was not
identical with any known element. He proposed the name
Tellurium from tellus, earth (Crell Annal. (1798) i, 91).

Occurrence. Tellurium occurs in combination and also,
sparingly, native.

Petzite, (Ag,Au)3Te,
Goldschmidtite, Ati^AgTee,
Hessite, Ag^Te,
Altaite, PbTe,
Coloradoite, HgTe,
Melonite, Ni^Te,,
Kalgoorlite, HgAu^AgeTee,
Sylvanite, (Au,Ag)Te3,
Calaverite, ( Au, Ag) Te^ • AuTe^,
Ejrennerite, (Au,Ag)Te3-AuTe2,
Nagyagite, AUjPbj^SbjTelySi^,
Tapalpite, 3Ag3(S,Te) .Bi3(S,Te)3?,
Tetradymiie, BijTejSj,
Grunlingite, Bi^TeS,,
Rickardite, Cu^Te • 2CuTe,
Joseite, formula doubtftil,
WehrHte, *'
Stutzite, Ag^Te ?,
Tellurite, TeOy

contains

i<

((

a

n

n

<<

li

<(

n

n

a

a

ti

<<

((

u

a

32-35% Te

59-60%

37-44%

37-38%

38-39%

73-76%

37-56%
58-62%

56-58%

38-59%

15-31%
20-24%

33-49%
12-13%

59-60%

15-16%

29-35%
22-23%

79-80%

so8

THE RARER ELEMENTS.

Montanite, Bi,(OH),TeO,?,
Emmonsite, formula doubtful,
Durdenite, Fe,(TeO,), -411,0,
Tellurium (native), Te,
Selen-tellurium, ^TesSe,

24-28% TeO,
S9-6o% Te
47-64% TeO,
93-97% Te
70-71

foil

_1 '

rated

Extraction, Tellurium may be extracted by the fol
lowing methods:

(i) From tellurium bismuth {teiradymite). The mineral
is mixed with its own weight of sodium carbonate, and
oil is added tintil the mass has the consistency of thick
paste. This is heated strongly in a well-closed crucible
and then extracted with water. The extract, containing
sodium sulphide and sodium telluride, (NajTe), is separated
by filtration from the insoluble matter and left expose
to the air. The tellurium separates as a gray powder,
may be purified by distillation (Berzelius).

(2) Froiti sylvaniie or nagyagite. The nmieral is treat<
with hydrochloric acid, which dissolves the antimon^
arsenic, etc. The residue is dissolved in aqua regia, the
excess of acid is removed by evaporation, and the gold is
precipitated by ferrous sulphate. After the removal of
the gold by filtration the tellurium is precipitated by sul
phur dioxide (Von Schrotter).

(3) From flue-dust containing tellurium. The materi
is treated with strong commercial hydrochloric acid (w
Experiment 109).

The Element. A. Preparation. Elementary telluritU
may be obtained (i) by the action of reducing agents, E
sulphurous acid or stannous chloride, upon the salts of t
lurium; and {2) by the action of air upon soluble telluridej

B. Properties. Telliirium is generally considered a
metal, though Berzelius classed it with the metals. It i
known in two conditions: (i) the crystalline, in which the
element has a luster like silver, and (2) the amorphous. It-^::

TELLURIUM, 109

IS unchanged in the air at ordinary temperatures, but when
heated in air or oxygen it bums with a green flame, forming
the dioxide (TeOj). It is not attacked by hydrochloric
acid, but is acted upon slowly by concentrated sulphtiric
acid, with evolution of sulphur dioxide. It is oxidized by
nitric acid and aqua regia to tellurous acid, (HjTeOg), and
is dissolved in hot caustic potash, forming the telluride
and tellurite (K^Te; KjTeOg). It combines with metals,
to form tellurides. Like selenium and sulphur, it is a poor
conductor of heat and electricity. Its specific gravity is
from 6.1 to 6.3.

Compounds. A. Typical forms. The following are typ-
ical compoimds of telltirium:

Oxides TeO TeO^ TeOj

Chlorides TeCl^ TeCl,

Oxychloride TeOCl^

Bromides TeBr^ TeBr,

Oxybromide TeOBr2

Iodides Tel^ Tel,

Fluoride TeF,

Double fluoride TeF, • KF

Sulphite TeSOg

Sulphate 2Te02 -SO,

Sulphides (or sulpho salts) . TeSj • 3 K2S •

TeSj • BijSg, etc.
Tellurides H^Te

AS^TCg

KjTe, etc.
Acids (tellurous and telluric) HjTeOg H^TeO,*

Salts (telltirites and tellurates) RjTeOg RzTeO,

B. Characteristics. The compoimds of tellurium closely
resemble in general structure those of sulphur, and, as will
appear later, those of selenium. Hydrogen telluride, (HjTe) ,

* Gutbier favors the formula HjTeOo.

THE R^RER ELEMENTS.
like hydrogen sulphide, is a gaseous substance, and it pre-
cipitates metallic tellurides, (R^Te), similar to the sulphides.
Two oxides, tellurous, {TeOJ, and telluric, (TeO,), are well
known,* but, unlike the corresponding oxides of sulphur,
they are very sparingly soluble in water. The acids,
(HjTeO^; HjTeO,), may be formed by acidifying solutions
of the alkali salts (e.g. NajTeO^ or Na^TeO,) which have
been formed by the action of the alkaH hydroxides upon
the oxides (TeO,; TeOJ. Many tellurites and tellurates,
(RjTeO,; R,TeO,), may be formed by treating the alkali
tellurites or tellurates with soluble salts of the various
bases. Two chlorides are known, (TeClji TeCl,), both of
which are decomposed by water. The corresponding
bromides and iodides are also known. In general, com-
pounds of tellurium are easily reduced to the element.
The reduction, however, is not accomplished qmte so
readily as in the case of selenium compoimds.

Estimation.t A. Gravimetric. Tellurium is usually
weighed as the element, obtained by treating solutions
of tellurium compounds (i) with sulphur dioxide; (a)
■with hydrazine sulphate in ammoniac al solution (Jan-
nasch. Ber. Dtsch. chem. Ges. xxxi, 2377); (3) with hydra-
zine hydrate or its salts in acid or alkaline solution (Gut-
bier, Ber. Dtsch. chem. Ges. xxxiv, 2724); (4) with sul-
phtu" dioxide and potassium iodide (Frericks, J. pr. Chem.
[2] Lxvi, 261); (5) with hypophosphorus acid (Gutbier,
Zeitsch. anorg. Chem. xxxii, 295); (6) with grape-sugar
in alkaline solution (Stolba, vid. Kastner, Zeitsch. anal,
Chem. XIV, 142) ; or (7) with acid sodium sulphite or mag- ,
nesium {vid. Experiment 109).

It may be weighed also as the sulphate, (2Te0j-S0j),

* A monoxide, (TeO), also has been described.

t See Gutbier, Studien uber das Tellur, pub. by Hirsclifeld, Leipzig, igoa;
Mac Ivor, Chem. News Lxxxvii, 17, i6;.

I

I

TELLURIUM. Ill

obtained by treating elementary telluritim with a mixture
of nitric and sulphtiric acids and evaporating (Metzner,
Ann. Chim. Phys. [7] xv, 203).

B, Volumetric, Telltirium may be estimated volumet-
rically (i) by the reduction of telluric acid to tellurous by
means of potassium bromide in sulphuric acid solution,
(H2TeO, + 2HBr = H2Te03 + H30 + Br3, the bromine being
passed into potassium iodide, and the iodine estimated
by standard thiosulphate (Gooch and Rowland, Amer.
Jour. Sci. [3] XLViii, 375); (2) by the reducing action of
strong hydrochloric acid upon soluble tellurates, chlorine
being set free and passed into potassium iodide with libera-
tion of iodine, as above; (3) by the action of standard
potassium iodide solution upon a solution of tellurous
acid containing twenty-five per cent, by volume of strong
sulphuric acid, (H2Te03 + 4H2SO, + 4KI=TeI, + 4KHSO,+
3H3O), tellurous iodide being precipitated as a black, curdy
mass, which, when shaken, separates in such a manner that
the point when precipitation ceases can easily be detected;
the quantity of telltirium present is calculable from the
quantity of potassitim iodide used (Gooch and Moi^an,
Amer. Jour. Sci. [4] 11, 271); (4) by the oxidation of tellur
rous acid by means of standard potassitmi permanganate
in acid or alkaline solution (Norris and Fay, Amer. Chem.
Jour. XX, 278; Gooch and Peters, Amer. Jour. Sci. [4]
VIII, 122).

Separation.* From the elements not easily reduced
from their compoimds to elementary form, tellurium may
be separated in general by the action of sulphur dioxide in
faintly acid solution ; this precipitates elementary tellurium.
From bismuth telluritim is separated by the action of
potassium sulphide upon the precipitate thrown down
from solutions by hydrogen stdphide, — ^the tellurium dis-

♦ See Gutbier, Studien uber das Tellur.

I

THE /14RER ELEMENTS.

solving. From antimony the separation may be accom-
plished (i) by hydrazine hydrate, the tellurium being pre-
cipitated {Gutbier, Zeitsch. anorg. Chem. xxxii, 260);
(2) by treatment of a solution of sulpho-tellurite and sul-
pho-antimonite with 20% hydrochloric acid io the pres-
ence of tartaric acid, the tellurium separating out (Muth-
mann and Schroder, Zeitsch. anorg. Chem. xiv, 433). From
silver tellurium is separated by hydrochloric acid, the
silver being precipitated ; from gold by the action of heat
on the two metals, tellurium being volatilized; from mer-
cury by the action of phosphorus acid upDn a cold dilute
hydrochloric acid solution of the salts, mercurous chloride
being precipitated.

From selenium tellurium may be separated (i) by
hydroxylamine in strong hydrochloric acid solution, the
selenium being precipitated (Jannasch and Muller, Ber.
Dtsch. chem. Ges. xxxi, 2388) ; (2) by sulphur dioxide in
strong hydrochloric add solution, selenium being pre-
cipitated (Keller, Jour. Amer. Chem. Soc. xix, 771, and
XXII, 341}; (3) by fusion of the elements with potassium
cyanide in the presence of hydrogen, tellurium being pre-
cipitated when air is passed through a solution of the melt;

(4) by the action of ferrous sulphate {vtd. Experiment 109) ;

(5) hy the greater volatility of the bromide of selenium
(Gooch and Peirce, Amer. Jour, Sci. [4] 1, 181),

EXPERIMENTAL WORK ON TELLURIUM.

Experiment 109. Extraction of tellurium from flue-dust, or
from waste products from the electrolytic refining of copper.
Treat about logrm, of the material with strong commercial
hydrochloric acid until nothing further dissolves, and filter.
To a small portion of the filtrate add ferrous sulphate, and
warm gently. The presence of seleniiun will be indicated by
a reddish precipitate. If selenium has thus been shown to

.'^

EXPERIMENTAL ^ORK ON TELLURIUM. 113

<»

be present, take about 5 cm.* of the original filtrate, precipi-
tate the selenium and telltirium by acid sodium sulphite or by
magnesium, wash this precipitate, return it to the remainder
of the filtrate, and heat to boiling. The selenium present
will be precipitated by the telltirium. Remove the selen-
ium by filtration and set it aside for later use (vid. Experi-
ment 119). From the filtrate precipitate the telltirium
by acid soditim sulphite or by magnesitim (Crane, Amer.
Chem. Jotir. xxxiii, 408).

Experiment no. Action of strong sulphuric acid upon
tellurium. To a small amotint of elementary telluritim
add a few cm.' of strong sulphuric acid and warm. Note
the reddish- violet color. This reaction constitutes a good
test for tellurium.

Experiment in. Preparation of tellurium dioxide^ (TeOj).

To a small amotmt of elementary telltirium add nitric

acid, evaporate to dryness, and heat gently.

Experiment 112. Formation of an alkali tellurite ^
I
(RjTeOg). Dissolve a little tellurium dioxide in a solution

of sodium or potassium hydroxide.

Experiment 113. Formation of telluric acid, (H2TeO^).
To a solution of an alkali tellurite add sulphuric acid tmtil
the precipitate first formed dissolves. Then add gradually
a solution of potassium permanganate until no ftirther
bleaching action is noticed.

Experiment 114. Reduction of telluric acid. To a solu-
tion of telluric acid prepared in the previous experiment
add a little potassium bromide and sulphuric acid, and boil.
Note the evolution of bromine and the reduction to tellu-
rous acid.

Experiment 115. Precipitation of tellurous iodide, (Tel^).
To a solution of an alkali tellurite add sulphuric acid until
the precipitate first formed dissolves. Then add a few
drops of a solution of potassitim iodide. Note the black
precipitate.

"4

THE RARER ELEMENTS.

Experiment ii6. Precipitation of elementary tellurium.
Try the action of the following reducing agents upon sepa-
rate portions of an acid solution containing tellurium:
stannous chloride, hydrogen sulphide,* sulphurous acid,
magnesium, and acid sodium sulphite {vid. Experiment 109).

Experiment 117. Action of lellurium compomids before
the blowpipe. Heat on charcoal a small amount of a tellu-
rium compound. Note the white sublimate and the green
color imparted to the reducing flame.

Experiment 118. Negative test of tellurium. Try the
action of ferrous sulphate upon an acidified solution of
a tellurite.

SELEimrM, Se,

79.1

Discovery, For some time previous to the discovery
of selenium a red deposit had been noticed in the lead
chambers used in the manufacture of sulphuric acid at
Gripsholm in Sweden. The deposit was present when the
sulphur employed had been prepared from pyrites from
Fahlun, Sweden, but was seldom observed when the sulphur
had been obtained from other sources. At first the un-
known substance was supposed to be sulphur. When it
was burned, an odor as of decayed cabbage was given off,
and this was supposed to be caused by the presence of
tellurium sulphide, although no tellurium could be ex-
tracted from the material. In 1817 Berzelius, having
become a shareholder in the acid works, examined the
red deposit, and in a short time he announced the dis-
covery of a new element. Because of its frequent associa-
tion with tellurium, and its many points of similarity to
that element, he named it Selenium, from ae\ijvtf, the
moon (Annal. der Phys. u. Chem. (1818) xxix, 229).

• Some authors give TcSj a
drogen sulphide.

of the precipitate by hy-

SELENIUM.

"5

Occurrence. Selenium is fotind usually in combina-
tion with the metals, as in the following minerals:

Clausthalite, PbSe,
Tiemannite, HgSe,
Guanajuatite, BijSej,
Naumannite, (Ag2,Pb)Se,
Berzelianite, Cu^Se,
Lehrbachite, PbSe-HgSe,
Eucairite, CUjSe-AgjSe,
Zorgite, vid, Clausthalite,
Crookesite, (Cu,Tl,Ag)j,Se,
Onofrite, Hg(S,Se),
Galenobismutite, PbBi^S^,
Durdenite, Fej,(Te03)3 -411,0,
Chalcomenite, CuSeO, • 2H3O,
Telluritim (native), Te,
Selen-sulphur, :x:Se -yS,
Selen-tellurium, 3Te • 2Se,

contains •

• . . (

27-28% Se

25-29% "
24-34% "

27-30%
39-40%
24-28%

31-32%

29-34%

30-33%
4- 6%

0-14%

I- 2%SeO,

48-49% "
6- 7%Se

35-66% "

29-30% "

<<

<<

<<

<(

<<

<(

(<

ti

Extraction. Selenium salts may be extracted from flue-
dust by the following methods:

(i) The soluble material is dissolved by treatment
with water, and the selenium is extracted from the residue
by aqua regia (Berzelius, vid. Experiment 119).

(2) The seleniferous material is digested with a solu-
tion of potassium cyanide at a temperature of 8o°-ioo° C.
until the red color has changed to gray, (KSeCN). The
selenium goes into solution and may be precipitated by
hydrochloric acid (Pettersson, Ber. Dtsch. chem. Ges.
VII, 1719).

(3) The flue-dust or mineral is fused with sodium car-
bonate, and the selenitmi is extracted with water as sodivmi
selenide and selenite, (NajSe; NajSeOg).

ii6

THE RARER ELEMENTS.

The Element. A. Preparation. Selenium in the ele-
mentary condition may be prepared by the action (i) of
sulphur dioxide, zinc, or iron, upon selenious acid (Ber-
zelius); {2) of hydrochloric acid upon sodium seleno-siU-
phite (Pettersson) ; (3} of potassium iodide, sodium thio-
sulphate, etc., upon selenious acid.

B. Properties. Like sulphur, selenium is knc
several allotropic modifications,* and may be either solubl
or insoluble in carbon disulphide. In soluble form selen-
ium is a red powder which softens at so°-6o° C, is partly
fluid at 100° C. and is completely fused at 250° C . After
it has been melted it remains in a plastic condition for
long time and has a metallic luster. Its specific gravit;
is 4.3 to 4.3. From a warm solution in carbon disulphii
the element separates in red, monoclinic, crystalline plate^^
and from a cold solution in orange-red monoclinic ci
tals of different type. The specific gravity of these ci
talline varieties is 4.4 to 4.5. Selenium insoluble in carl
disulphide may be obtained by allowing the element to'
cool very slowly after it has been heated to a higher tem-
perature than 130° C, or by allowing the oxygen of the
air to act upon selenides in aqueous solution. Under
these conditions the element asstlmes the so-called metallic
form, crystallizes in steel-gray hexagonal crystals, and
becomes isomorphous with tellurium. Metallic seleniiinx
melts at 217° C. without previous softening. Its spec
gravity is 4'.8.

Selenium boils at 700° C, yielding a dark-yellow va]
which, when condensed and cooled, assumes a form simi]
to flowers of sulphur; this is called flowers of selenii
The element is soluble in sulphuric acid, giving a green solu-
tion, and is oxidized by nitric acid to selenious acid, (HjSeO,),

4

>i^

* For a rece
Cfaem. (1900) 1'

1: discussion of these modifications see Saunders, Jour. Phyl

SELENIUM. 117

It combines with metals to form selenides. When heated
in air or oxygen it bums with a blue flame and goes over
to the dioxide, (SeO,). It is a poor conductor of heat and
electricity.

Compounds. A. Typical forms. The following com-
potmds of selenium may be considered typical:

Oxides SeOj SeO,

Chlorides Se,Cl, SeCl,

SeC^Br

Oxychloride SeOCl,

Bromides ScjBr, SeBr^

SeClBr,

Iodides Scjla Sel^

Seleno-sulphite .... SeSO,

Alums R^l2(SeO^)^ + 24HP

Thioselenic acid. . . H^SSeO,

Thioseleniate K,SSeO,

Cyanides (CN)3Se

(CN)3Se,

H(CN)Se

K(CN)Se

R(CN)Se,

Kitride N,Se

Phosphides ^^t

PjSe,
Selenides H,Se

NiSe

Ag^Se

KjSe, etc.

Acids (selenious and selenic) H^SeO, H^SeO^

I I

Salts (selenites and seleniates) R^SeO, R^SeO^

B. Characteristics. The compounds of selenium closely
lesenibfe those of tellurium, both in structure and in behavior

ii8

THE RARER ELEMENTS.

toward reagents. They are, however, rather more sensi-
tive to the acton of reducing agents, and readily precipitate
the red, amorphous variety of the element, which tends to
become black when heated. Hydrogen selenide is a gas
which acts like hydrogen sulphide and hydrogen teUuride,
and precipitates the selenides (RjSe). By the treatment
of elementary selenium with nitric acid or aqua regia
and evaporation to dryness, selenious oxide, (SeOj), is
formed, which dissolves in water, forming selenious acid,
(HjSeOg). By the action of powerful oxidizing agents,
such as chlorine, bromine, or potassium permanganate,
selenious acid may be oxidized to selenic acid, {H,SeO,),
which "is not reduced by sulphur dioxide. These acids
form salts of the types RjSeO, and R,SeO,. By the action
of reducing agents, such as sulphur dioxide or ferrous
sulphate, red amorphous selenium may be readily pre-
cipitated from selenious acid. Two chlorides, (ScjCl,;
SeClj), and the corresponding bromides and iodides are
known. When selenium is heated, a characteristic, pene-
trating odor is given off which has been variously described
as like that of garlic, decayed cabbage, and putrid. horse-
radish. This odor is caused by the formation of small
amounts of the hydride.

Estmiation. A. Gravimetric. Selenium is generally
weighed as the element, obtained by treating solutions
of its compounds (i) with sulphurous acid in hydrochloric
acid solution; (2) with potassium iodide in acid solution
(Peirce, Amer. Jour. Sci. [4] i, 416); (3) with hypophos-
phorus acid in alkaline solution (Gutbier and Rohn, Zeitsch.
anorg. Chem. xxxiv, 448). Other reducing agents may be
ixsed.

B. Volumetric. Selenium may be determined volu-
metrically (i) by oxidizing selenious acid to selenic by
means of standard potassium permanganate in sulphuric
acid solution, using an excess of permanganate, and titrat-

SELENIUM. 119

ing back with oxalic acid (Gooch and demons, Amer.
Jotir. Sci. [3] L, 51) ; (2) by reducing selenic or selenious acid
by means of potas ium iodide in hydrochloric acid solution,
(SeO, + 4HI=2H30 + Se + 2l3;Se'03 + 6HI=3H20 + Se + 3l2),
and determining by appropriate means the iodine set free
(Muthmann and Schaefer, Ber. Dtsch. chem. Ges. xxvi,
1008; Gooch and Reynolds, Amer. Jour. Sci. [3] l, 254);
(3) by reducing selenic acid to selenious by boiling with
hydrochloric acid, (Se03 + 2HCl=Se03 + H20 + Cy, then
passing the free chlorine into potassium iodide, and deter-
mining the iodine set free (Gooch and Evans, Amer. Jour.
Sci. [3] L, 400) ; (4) by employing potassium bromide and
sulphuric acid instead of hydrochloric acid in (3) (Gooch
and Scoville, Amer. Jour. Sci. [3] l, 402); (5) by boiling
a solution of selenious acid with sulphuric acid, a known
amotmt of potassitun iodide, and an excess of arsenic acid ;
the reduction of the selenious acid will decrease the reduction
of arsenic acid; the quantity of arsenious acid present at
the close of the action may be measured, after neutral-
ization with potassium bicarbonate, by standard iodine
(Gooch and Peirce, Amer. Jour. Sci. [4] i, 31); (6) by the
reduction of selenious acid to elementary selenium by
means of standard sodium thiosulphate solution in excess
in the presence of hydrochloric acid, — ^the excess of thio-
sulphate being determined by standard iodine solution
(Norris and Fay, Amer. Chem. Jour, xviii, 703; Norton,
Amer. Jour. Sci. [4] vii, 287) ; (7) by boiling elementary
selenium with ammonia and standard silver nitrate solution,
acidifying with nitric acid, and determining the excess
of silver nitrate by ammonium sulpho-cyanide, with ferric
alum as indicator; the quantity of selenium present is
calculable from the quantity of silver nitrate used, as is
shown in the following equation: 4AgX0,-f 3Se-r3H20
= 2AgaSe + H,SeO, + 4HNO, (Friedrich, Zeitsch. angew.
Chem. XV, 852).

»»o THE RARER ELEMENTS.

Separation. Selenium is separated, together with tel-
lurium, from other elements by methods given under
Tellurium. Methods of accomplishing the separation of
these two elements from each other have also been
scribed.

EXPERIMENTAL WORK ON SELENIUM.

dej

Experiment 119. Extraction of selenium from (i) flue-
dust and {2) seleniferous residues from the electrolytic refining
of copper, (i) Treat about 25 grm. of the washed flue-
dust with aqua regia as long as any evidence of action is
observed, and evaporate to dryness. Extract the residue
with about 25 cm." of strong common hydrochloric acid,
and filter. To the filtrate add about a gram of dry ferrous
sulphate, and warm gently if necessary. Filter off the red
amorphous selenium.

(2) To free the selenium obtained in Experiment 109
from the excess of tellurium present (a) treat the material
with hydrochloric acid and either a little chlorine or a drop
of nitric acid. Precipitate the selenium by ferrous sulphate.
(b) Or warm the material with a dilute solution of potassium
cyanide. The selenium goes into solution as potassium
seleno-cyanide and may be precipitated by acidifying the
solution with hydrochloric acid.

Experitneni 120. Preparation of selenium dioxide, (SeO,).
To a small amount of elementary selenium add nitric
acid until the oxidation is shown to be complete by
the cessation of the evolution of red fumes (oxides of
nitrogen). Evaporate to dryness and warm gently. The_
white residue is selenium dioxide. Dissolve this in a. litti
water to form selenious acid, (HjSeOJ.

Experiment 121. Precipitation of barium seteniti
(BaSeOj). To a Httle selenious acid add a few drops <

EXPERIMENTAL IVORK ON SELENIUM, I2X

a barium salt in solution. Test the action of hydro-
chloric acid upon the precipitate.

Experiment 122. Formation of selenic acid, (H^SeOJ.
To a few cm.' of selenious ac-d add first a small amount
of sulphtiric acid and then a solution of potassium per-
manganate until the purple color is permanent. Bleach
by the careful addition of oxalic acid.

Experiment 123. Reduction of selenic acid to selenious.
Add to a given volume of selenic acid half as much strong
hydrochloric acid and boil to about two thirds of the total
volume. Note the evolution of chlorine. Test by starch
iodide paper.

Experiment 124. Precipitation of elementary selenium.
Try the action of the following reducing agents upon dilute
selenious acid: sulphur dioxide, hydrogen sulphide, acid
sodium sulphite, potassium iodide, stannous chloride,
ferrous stdphate.

Experiment 125. Solvent action of carbon disulphide
upon selenium. To a little dry, washed, amorphous selen-
ium add carbon disulphide. Filter, and allow the filtrate
to evaporate.

Experiment 126. Solvent action of potassium cyanide
upon selenium. To a small amount of the red amorphous
selenium add a few cm.' of a dilute solution of potassium
cyanide (poison!), warm gently, and filter. To the filtrate
add hydrochloric acid.

Experiment 127. Behavior of selenium when subjected
to heat. Heat a small amovint of elementary selenium on
a glass rod. Note the odor, and the color of the flame.

Experiment 128. Action of strong sulphuric acid upon
selenium. To a small amotmt of elementary selenium add
a few cm.' of strong sulphuric acid- and warm. Note the
color. Compare with telltiritun {vid. Experiment no).

THE RARER ELEMENTS.

PLATINUM, Pt, 194-8.

DiBCOvery. In the year 1750 William Watson preseni
to the Royal Society a communication from Willij
Brownrigg in which was described a ' ' semi-metal
Platina di Pinto ' ' found in the Spanish West Indies,
son stated that, so far as he knew, no previous mention had
been made of this substance except by Don Antonio de
.Ulloa in the history of his voyage to South America, pub-
lished in Madrid in 1748 (Phd. Trans. Roy. Soc. (1750)
XLVi, 584). However, an earlier discovery is suggested by
a statement of Scaliger in 1558, who, in combating the
opinion of Cardanus, that all metals are fusible, declared
that an infusible metallic substance existed in the mines of
Mexico and Darien. As platinum is found in those coun-
tries, it is probably the metal referred to The name
Platinum is derived from the Spanish platina, the diminu-
tive of plaia, silver.

Occurrence. Platinum occurs alloyed with the varioi
metals of its group — palladium, osmium, iridium, etc. — and
iassocjated with other metals, as iron, lead, copper, titanic
iron, etc. It is found chiefly in the Ural Mountains, but
also in Brazil, Mexico, Borneo, California, North Carolina,
and elsewhere. It comprises from fifty to eighty per cent,
of the alloys in which it occurs. Platinum is found com-
bined in the mineral sperrylite, PtAs,, which contains al
fifty-three per cent, of the metal.

Extraction. Platinum may be extracted from its
by the following methods:

(i) Fusion process. The material is fused with si
phide of lead. The iron present combines with the si
phur. The platinum alloys with the lead, while the
mium and iridium do not. The lead-platinum alloy
separated from the mass and cupelled. The platinum
left (DeviUe and Debray).

n4"

PLATINUM. 123

(2) Wet process. The pulverized alloy is heated in a
porcelain dish with aqua regia as long as action continues.
The solution obtained is neariy neutralized with calcium
hydroxide, and the iron, copper, rhodium, iridium, and part
of the palladium separate. After the removal of these, the
filtrate is evaporated to dryness and the residue is ignited
and treated with water and hydrochloric acid. The plati-
num, with traces of the platinum metals, remains.

The Element. A. Preparation, As extracted from its
alloys, platinum is in the elementary condition {vid. Ex-
traction) .

B. Properties. In its usual form, elementary platinum
is a grayish-white metal which is very malleable and
ductile, but fusible only in the oxyhydrogen blowpipe or
by means of the electric current. At no temperature is it
oxidized by water or oxygen, or attacked by the simple
acids. It is soluble, however, in aqua regia. Platinum is
not acted upon by sulphur alone, but if alkalies are present
with the sulphur some action takes place. It is attacked
also when heated with potassium nitrate. Its specific
gravity is 21.48.

Besides the ordinary form, the element platinum is
known to exist in two allotropic conditions: (i) spongy
platinum, obtained by the ignition of ammonium chloro-
platinate, and (2) platinum-black, obtained by reducing
acid solutions of platinum salts. In both of these forms
platinum condenses gases on its surface.

Compounds. A. Typical forms. The following may be
regarded as typical compoimds of platinum:

Oxides. PtO Pts04 PtOj

Chlorides PtCla PtCl,

Double chlorides PtCl2-SrCl2+ PtCl^ • 2AgCl, etc

6H2O, etc.

Bromides PtBfj PtBr^

Double bromides PtBrj- 2KBr, etc PtBr4-SrBra+ loHjO

Iodides Ptlj Ptl^

i

124 THE RARER ELEMENTS.

Double iodides Ptl^ • 2KI, etc.

Fluorides PtF, PtF^

Sulphides PtS PtSj

Oxysulphide PtOS

Sulpho salts RjPtSe

Sulphites PtSOj-RjSOj; PtS03.2Ra

Nitrites R,(N0j)4Pt

lodonitrites Ra(N02)2l,Pt

Cyanide Pt(CN)3

Hydro - platino - cyanic
acid HjPtCCN)^

I II

Platino-cyanides RjPt(CN)4; RPtCCN)^, typical

Chloroplatinic acid. , . . HaPtCl,

I II

Chloroplatinates RjPtCl,; RPtCl,, typical

B, Characteristics, The compounds of platinum may-
be divided into two classes, of which the platinous and
platinic oxides, (PtO; PtOj), serve as types. The salts of
the lower condition of oxidation are usually colorless or
reddish brown; they give with hydrogen sulphide or am-
monium sulphide a dark-brown precipitate of platinous
sulphide, (PtS), which is soluble in ammonium sulphide.
They are decomposed at red heat, and are slowly reduced
to metallic platinum when boiled with ferrous sulphate.
The salts of the higher condition of oxidation have a yellow
or brown color, and like the platinous salts they are de-
composed at red heat. Metals in general and organic
matter precipitate platinum from solutions of platinic
salts. The brownish-gray platinic sulphide, (PtSj), is pre-
cipitated by the action of hydrogen sulphide upon a solu-
tion of chloroplatinic acid, (HjPtClg) ; this sulphide dissolves
slowly in ammonium sulphide. Salts of potassium and

ammonium act upon chloroplatinic acid precipitating the

I
corresponding salts of that acid, (RjPtCle) . When platinous

chloride dissolves in potassium cyanide, platinum potas-

PLATINUM. 125

sium cyanide is formed, (K2Pt(CN)4 + 4H20). Many salts
of this type are known.

The platinum-ammonium compoimds comprise a large
number of complex salts of the following types:

(a) The platosamines, PtR^CNHg),.; PtR2(NH3)3;
PtRjCNH,)^; PtR^CNHg); and (6) the platinamines,
PtR,(NH3),; PtR.CNH,),; PtR.CNH,)^; PtR.CNHJ.

In the above formulae R may stand for OH, CI, Br, I,
or NO3. These compotmds are formed by the action of
ammonia upon the platinum salts.

Potassium iodide gives a red-brown color to very dilute
solutions of platinum salts.

Estimation. A. Gravimetric. Platinum is generally
weighed as the metal, obtained (i) by precipitation from
solutions of compoimds by means of appropriate reducing
agents, such as formic acid, alcohol in alkaline solution, or
magnesium (Atterberg, Chem. Ztg. xxii, 538) ; (2) by pre-
cipitation of the sulphide and ignition; (3) by precipitation
of ammonium or potassium chloroplatinate, and decomposi-
tion by heat into the metal and the volatile or soluble
alkali chloride.

B. Volumetric. Platinum may be estimated volumet-
rically by reducing the tetrachloride by means of potas-
sium iodide, (PtCl4 + 4KI=Ptl2 + l2 + 4KCl), and determin-
ing by standard sodium thiosulphate the iodine thus liber-
ated (Peterson, Zeitsch. anorg. Chem. xix, 59).

Separation. From most other elements platinum may
be separated by the action of reducing agents in precipitat-
ing the metal from solutions. From the metals with which
it is most often found associated it may be separated by
the following methods: from gold (i) by the action of
ammonium chloride upon the chlorides, ammonium chloro-
platinate being precipitated; (2) by the action of hydro-
gen dioxide and sodium hydroxide upon cold solutions,
the gold being precipitated (Vanino and Seeman, Ber. Dtsch.

"5 THE RARER ELEMENTS.

chem. Ges. xxxii, 1968) ; (3) by the action of oxalic add or

ferrous salts, gold being again precipitated (Hoffmann and
Kruss, Zeitsch. anal. Chem. xxvii, 66; Bettel, Chem. News
LVi, 133); from silver by heating the metals with concen-
trated sulphuric acid, silver dissolving (Richards, The
Analyst, xxvn, 265) ; from mercury by ignition of the
metals, mercuiy being volatilized. 1^

The separation of platinum from the other^fctinum
metals is so involved with the separation of theS from
each other that the whole subject will be briefly considered
in this place. The following methods have beeA,suggested,
(i) The ore is first treated with chlorine water, wtich ex-
tracts the gold, then with dilute aqua regia, which dis-
solves the platinum, palladium, and rhodium. From this
solution the platinum is precipitated by ammonium chloride
and alcohol; and from the filtrate, after neutralization with
sodium carbonate, the palladium is precipitated as the
cyanide by mercury cyanide. The residue from the aqua
regia treatment, containing osmium, iridium, and ruthe-
nium, is heated in air, Osmium is volatilized as the tetrox-
ide, ruthenium sublimes as the dioxide, and iridium is
left (Pimgriiber, J. B. (1888), 2560; Wyatt, Eng. and Min.
J. XLiv, 273). (2) A neutral or acid solution of the plat-
inum metals, gold, and mercury, containing chlorine, is
treated with dilute nitric acid and heated to boiling in a
retort ; osmic tetroxide distils. The solution is cooled, and
shaken with ether, which withdraws the chloride of gold.
After the removal of the ether and gold by means of a
separating funnel the remaining solution is treated with
ammonium acetate and boiled with formic acid. This
treatment precipitates all the metals, which are then heated
in a current of hydrogen to volatilize the mercury. The
remaining metals are mixed with sodium chloride and
heated with moist chlorine, and the mass is extracted with
water. If there is any residue at this point it will probably

»

»

PLATINUM. ««7J

be found to be iridium and ruthenium. The solution isj
treated with concentrated ammonium chloride as long aa \
any precipitate forms. This precipitate consists of the
double chlorides of ammonium with platinum, iridium, and
ruthenium respectively, palladium and rhodium remaining
in solution. The precipitate is dissolved in warm water
and treated with hydroxylamine, which reduces the irid-
ium and ruthenium to the condition of the sesquichlorides ; i
upon the addition of ammonium chloride platinum is pre-
cipitated as the chloroplatinate. The hydroxylamine fil-
trate is evaporated, the residue is heated in the presence of
hydrogen and fused with potassium hydroxide and nitrate,
the mass is cooled and extracted with water. Ruthenium
dissolves as potassium ruthenate, (K^RuOJ, and iridium
remains as the hydrate, (Ir(OH),). The solution contain-
ing rhodium and palladium is evaporated slowly to dryness
in the presence of an excess of ammonia, and the residue
is dissolved in the smallest possible amount of a warm, dilute
anmloniacal solution. Upon cooling, the rhodium separates
as a complex chloride, (RhCNHJjCl,), and the palladium
remains in solution (Mylius and Dietz, Ber. Dtsch. chem.
Ges. XXXI, 3187). (3) Gold is removed by means of dilute
aqua regia. By treatment with concentrated aqua regia
platinum, palladium, rhodium, ruthenium, and part of the
iridium are then dissolved, while an insoluble alloy of os-
mium and iridium in the form of grains or plates remains.
This alloy is mixed with sodium chloride and the mixture
is heated in a tube with chlorine. Osmium tetroxide,
(OsOj), distils, and sodium-indium chloride, (NajIrCl,), re-
mains (Wohler, Pogg. Annal. xxxi, 161). To the solution of
the other platinum metals in aqua regia ammonium chloride
is added. The precipitate, consisting of the double salts of
platinum and iridium, may by ignition be converted intq
iridium-bearing platinum sponge (used in the manufactura
of platinum vessels) . To the filtrate iron or copper is added.

sz8

THE R^RER ELEMENTS.

■Which throws down the palladmm, rhodium, and ruthenium
as a metallic powder. From this mixture palladium and
the iron or copper are dissolved by nitric acid, and the solu-
tion is then shaken with mercury, which removes the palla-
dium (von Schneider, Liebig Annal. v, 264, suppl.). The
mixture of rhodium and ruthenium remaining is heated with
sodium chloride at low redness in a current of chlorine and
the mass is extracted with water. This liquid is boiled
with potassium nitrite and enough potassium carbonate
to make the solution faintly alkaline. It is then evaporated
to dryness and the residue is pulverized and extracted
with absolute alcohol. The rhodium remains undissolved
as a double nitrite of potassium and rhodium, (K„Rhj(NOj),j,
while the ruthenium dissolves, also as a double nitrite with
potassium, (Ru(N0,)b-6KN0j).

Platinum may be separated from palladium (i) by the
action of warm dilute nitric acid upon the metals, palladium
dissolving; (2) by the action of a strong solution of am-
monium chloride and alcohol upon the double potassium
salts, the palladium salt being soluble (Cohn and Fleissner,
Ber. Dtsch. chem. Ges. xx:x, R. 876) ; from iridium (i) by
electrolysis, the platinum being precipitated (Smith, Amer.
Chem. Jour, xiv, 435) ; (2) by the action of potassium
nitrite, sodium carbonate, and boiling water upon the
double potassium salts, iridium being reduced to the con-
dition of the sesquichloride and dissolved (Gibbs, Amer,
Jour, Sci. [z] XXXIV, 347); from osmium by heating in the
presence of oxidizing material, osmium tetroxide being
formed and volatilized; from ruthenium by treating potas-
sium chloroplatinate and the corresponding ruthenitun
salt with cold water, the ruthenium salt dissolving (Gibbs,
loc. cit.); from rhodium (i) by the method described for
the separation from ruthenium; or (2) by the action of
concentrated solutions of the alkali chlorides upon these
Gaits, the rhodium dissolving (Gibbs, loc. cit.).

EXPERIMENTAL IVORK ON PLATINUM. 129

EXPERIMENTAL WORK ON PLATINUM.

Experiment 129. Preparation of chloroplatinic acid from
laboratory residues. Boil the residues consisting of po-
tassitun chloroplatinate, etc., with a solution of sodium
carbonate and add a little alcohol. The platinum is de-
posited as a black powder. Wash the powder, first with
hot water, then with hot hydrochloric acid; dry it, dis-
solve it in aqua regia, evaporate the liquid, adding a little
hydrochloric acid from time to time to remove the nitric
acid, imtil the point of crystallization is reached.

Experiment 130. Precipitation of the chloroplatinates

of ammonium, potassium, ccBsium, rubidium, and thallium,

I
(RjPtCle). To separate portions of a solution of chloro-
platinic acid add salts of ammonitmi, potassitmi, caesium^,
rubidium, and thallitmi in solution. Note the compara-
tive insolubility of the new compounds in water and ia
alcohol.

Experiment 131. Precipitation of platinic sulphide,
(PtSj). To a solution of chloroplatinic acid add a little
hydrogen sulphide, and warm.

Experiment 132. Precipitation of elementary platinum.
(a) To a solution of a platinum salt add sodium carbonate
to alkaline reaction; add also a few drops of alcohol and
boil.

(6) Try the action of oxalic acid upon a platinum salt in
solution.

Experiment 133. Action of acids upon platinum. Try
separately the action of strong hydrochloric and nitric
acids upon metallic platinum. Note the effect of a mixture
of the two acids upon the metal.

Experiment 134. Test for platinum in solution. To a
very dilute solution of a platinum salt free from chlorine
add a small crystal of potassium iodide. Note the color.

130 THE RARER ELEMENTS.

THE PLATINUM METALS

OTHER THAN PLATINUM.

Occurring almost invariably associated with platinum
and usually alloyed with it are small quantities of certain
rare elements which, together with platinum, comprise
the group of so-called Platinum Metals. These very rare
elements are the following:

•

Palladium, Pd, 106 Osmium, Os, 191

Iridium, Ir, 193 Rhodium, Rh, 103

Ruthenium, Ru, 10 1.7

Discovery. In 1803, in the course of the purification
of a considerable quantity of crude platinum, Wollaston
isolated a new metal which he named Palladium, in honor
of the discovery by Olbers of the planetoid Pallas. The newly
discovered element was brought to the attention of scien-
tists anonymously through a dealer's advertisement, which
offered ** palladium or new silver" for sale. Much dis-
cussion as to the nature of the substance ensued, Chenevix,
in particular, holding it to be an alloy of platinum and mer-
cury. In 1805 Wollaston confessed to the discovery and
naming of the metal (Phil. Trans. Roy. Soc. (1803) xciii,
290; ibid. (1805) xcv, 316; Nicholson 's J. (1805) x, 204).

The same year that palladium was discovered, Smithson
Tennant found that ' * the black powder which remained after
the solution of platina did not, as was generally believed,
consist chiefly of plumbago, but contained some unknown
metallic ingredients." In 1804 he presented to the Royal
Society as the result of his study a communication announc-
ing the discovery of two new metals, Iridium, named ' * fro
the striking variety of colors which it gives while dissolvin;
in marine acid," and Osmium, so called because of tb

i

THE PLATINUM METALS.

penetrating odor {oa^ri. odor) of the acid obtained frcM
the oxidation of the element when it is heated in a find
divided condition (Phil. Trans. Roy. Soc. {1804) xciv, 411J!

A few days after Tennant's communication, Wollaston
announced the discovery of an element in the ' ' fluid which
remains after the precipitation of platina by sal ammoniac, ' '
and suggested the name Rhodium {poSios, rose-like), ' ' from
the rose color of a dilute solution of the salts containing
it" (Phil. Trans. Roy. Soc. (1804) xciv, 419).

In 1826 Osann claimed the discovery of three new ele-
ments in platinum alloys. These he named Ruthenium,
Pohnium, and Pluranium (Pogg. Annal, viii, 505; Amer.
Jour. Sci. XVI, 384). Later he withdrew the claim. In
1844 Claus found that there was an unknown metal in the
mixture of substances which had been called by Osann
"ruthenium oxide," and for it he retained the name
ruthenium, derived from Ruthenia, i.e. Russia, where the
substance was first found (Pogg. Annal. lxiv, 192, 208;
Amer. Jour. Sci. xlviii, 401).

Occurrence. The very rare platinum metals, as has
been already stated, are found in general in platinum-
hearing material. Palladium and iridium sometimes occur
native ; the others always in alloys or in combination.

Native platinum

Patladium gold
Iridosmine
Laurite, RuS,
Rhodium gold

Extraction. For methods of extraction of the very
rare platinum metals see Extraction and Separation of
Platinum.

The Elements. I. Palladium. A. Preparation. Ele-
mentary palladium may be obtained (i) by heating the
potassium double chloride -with hydrogen (Roessler) ; (2) by

*rr

*Rh

*Ru

aces-4.2
27-76.8

traces

circa 7

63

THE RARER ELEMENTS.

heating the iodide with hydrogen; and (3) by heating the
chloride or cyanide.

B. Properties. Palladium is a ductile, malleable, white
metal which looks like platinum. It may be partially
oxidized before the oxyhydrogen blowpipe. It is soluble
in strong nitric, hydrochloric, and sulphuric acids, and
easily soluble in aqua regia. It fuses at a lower temperature
than any other of the platinum metals. In spongy form
it has the power of absorbing gases. Its specific gravity
11.4-1T.8, Because of the color and hardness of pal-
ladium and its unalterability in the air it is used for the
r graduated surfaces of fine astronomical instruments. It
I may be distinguished from the other platinum metals by
[ the comparative ease with which it dissolves in nitric acid.

II. Osmium. A. Preparation. The element osmium:
j may be prepared ( i } by heating the amalgam in the presence
[ of hydrogen (Berzelius); (a) by heating the sulphjde in a

closed coke crucible ; {3) by passing the vapor of the tetroxide
mixed with carbon dioxide and carbon monoxide through a
heated porcelain tube; (4) by passing the vapor of the
tetroxide through a heated porcelain tube containing finely
divided carbon (Deville and Debray); (5) by igniting
osmyldiamine chloride, COs(NH,)jO,Clj), in a current o£
hydrogen.

B. Properties. Osmium, the heaviest of the platinum
metals, is a bluish substance, crystals of which are harder
than glass. In the compact form it is insoluble in all acids
and in aqua regia, and is rendered soluble only by fusion
with nitrates. The amorphous modification is slowly
soluble in nitric acid and in aqua regia. The specific gravity
of the compact and amorphous modifications is 21.3; of
the crystalline form 23.4. In the alloy iridosmine the
element is employed for compass bearings and for the
tips of gold pens.

III, Iridium. A. Preparation. MetaUic iridium may

^

THE PLATINUM METALS, 133

^e obtained (i) by heating iridium-ammonium chloride,
and (2) by heating iriditim-potassium chloride with soditim^
carbonate.

B. Properties, Iridium, a hard, brittle metal, resembles
-silver and tin in appearance. The ignited form is insoluble
in all acids and in aqua regia. The element is partially
oxidized, however, by fusion with sodium nitrate, and the
fused mass may be dissolved by boiling it with aqua regia.
In spongy form iridiimi has the specific gravity of 15.86;
after fusion the specific gravity is 21-22. Elementary iridium
is not used in the arts, but its alloy with osmiimi, as stated
above, is employed for compass bearings and for the tips
of gold pens; its alloy with platinum is used in the manu-
facture of laboratory vessels and for standard weights
and measures, and an oxide is used in ohina-painting.

IV. Rhodium. A, Preparation, Elementary rhodium
may be prepared (i) by heating ammonium-rhodiimi ses-
qtiichloride; (2) by heating rhodiimi sesquichloride and
sodiimi in a current of hydrogen; (3) by heating rhodium
sulphide to a white heat; and (4) by allowing reducing
agents, as formic acid, zinc, iron, alcohol in alkaline solu-
tion, hydrogen, etc., to act upon soluble salts.

B, Properties, Rhodium is a grayish- white metal which
has the appearance of aluminum. When pure it is almost
absolutely insoluble in acids and in aqua regia, but when
alloyed it m.ay be dissolved in aqua regia. It is fusible
before the oxyhydrogen blowpipe, but more difficultly
than platinum. It has the property of absorbing hydrogen.
Of all the platinum metals rhodium is most easily attacked
by chlorine. Its specific gravity is 11-12*. The alloy of
rhodium with steel is somewhat used in the arts.

V. Ruthenium. A, Preparation, The element ruthe-
nium may be obtained (i) by heating the oxide with illu-
minating-gas, and (2) by heating ruthenium-ammonium-
mercury chloride.

134

THE RARER ELEMENTS.

B. Properties. Ruthenitim is a hard, brittle metal,
dark gray to black in color. It is almost completely insolu-
ble in acids and in aqua regia; and osmium alone, of all
the platintim metals, is more difficultly fusible. It may
be slightly oxidized by fusion with caustic potash and
oxidized to a greater degree by fusion with potassitmi
nitrate. The specific gravity of the crystalline form is
12.26; of the melted form 11. 4; and of the porous form 8.6.

Compounds. A. Typical forms. The following com-
poimds of the platinum metals may be considered typical:

Oxides. Pd,0

PdO

OsO

IrO?

RhO

RuO

Os,0,

Ir,0,

Rh,0,

RujO,

PdO,

OsO,

(OSO3)*

OSO4

IrO,

RhO,

RuO,
(RuO,)*
RUO4
(Ru,0,)*

Chlorides. ...

...PdCl

PdCla

OsCla

IrCl,

RhCl,

RuCl,

OsCl,

Ir,Cle

Rh,Cl,

RujClf

PdCl4

OSCI4

IrCl4

RuCU

Bromides. . .

. ..PdBr,
PdBr4

Ir,Br,
IrBr4

Iodides

...Pdl,

Ir,IJ

Rh,I,

RuA

Irl4

Sulphides. . .

...Pd^

*

PdS

IrS

RhS

IrA

Rh^s

RuA

PdS,

OsS,
OSS4

IrS,

RuS,
RuSi

Sulphates. . .

. ..PdS04

Rh,(S04),

Ru(S04),

Sulphites

...PdSOg-
sNa^Os

OsSO,

Ir,(SO0,

Rh,(SO0«

Sulpho salts. .

. ..R3Pd8S4
R^PdSj

•

* This oxide is known only in combination.

THE PLATINUM METALS.

I3S

Nitrites. Pd(NOa),. 2KNO,

Nitrates Pd(NO,),

Adds and corre-

Ir,(NO,),.
6HN0a

RhaCNOJ,.
6RN0,

Rha(NO,),

Ru,(NO,),
6RN0,

spond'g salts.. . HjPdClf ;

RaPdCl4

HjOsCle;

i^RhCl,;

HjRuClj

RjOsCl,

RjRhCle

H,PdCl«;

HaOsCle;

HjRuCU

RjPdCle

RjOsCle

RjIrCl,

Characteristics. I. Palladium. The compounds of pal-
ladium resemble those of platinimi, both in form and
in general characteristics. As in the case of platinum,
palladium combines with ammonia to form complex salts,
and an oxide, (PdO), forms salts with sulphur dioxide and
with nitrogen trioxide, (N2O3). In general the salts are
quite easily reduced to the metal by heating ; their solutions
resemble a solution of platinic chloride in color. Two
oxides, (PdO; PdOj), are well known, of which the lower
forms the more stable compotmds. These compoimds give
a yellowish-brown precipitate with potassiimi hydroxide.
Solutions of palladium salts give with mercuric cyanide a
yellowish-white precipitate, (Pd(CN)2) ; with potassittm
iodide a black precipitate, (Pdlj), which is soluble in excess
of the reagent; and with hydrogen sulphide also a black
precipitate, (PdS), insoluble in ammonium sulphide.
Mercuric cyanide and potassiimi iodide are often used as
tests for palladium.

II. Osmium. Compounds of osmium are known in five
degrees of oxidation. The lowest three oxides, (OsO;
OS2O3; OsOj), are basic in character, the fourth,* (OsOj),
is acidic, and the fifth, (OSO4), is also acidic, but it forms

* Known only in salts.

13^ THE RARER ELEMENTS.

no salts. Three chlorides, (OsCl,; OsCl,; OsCl,), are knoi
corresponding to the lowest oxides. The metals sodinnij'

potassium, and barium fomi salts of the type RjOsO,.
These salts are readily decomposed, especially by acids, and
forra the dioxide and the tetroxide. When osmium com-
pounds are heated in the air with oxidizing agents, or are
melted with potassium nitrate, the tetroxide is obtained.
It is volatile when heated, highly corrosive, and disagree-
able like chlorine. It is soluble in water and is reduced
by reducing agents. From potassium iodide it frees iodine,
and with formic acid to which potassium hydroxide has
been added it gives a violet color. With ferrous sulphate!
it precipitates black osmium hydroxide, (Os(OH),), and'
with hydrogen sulphide it brings down the brownish-black
sulphide (OsSJ, which is insoluble in ammonium sulphide.
III. Iridium. The compounds of iridium exist chiefly
in three conditions of oxidation, of which the di-, tri-, and.
tetrachlorides may serve as types, (IrCl,; IrjClg; IrCljJ
The iridium compounds are reduced to the metal wh(
mixed with sodium carbonate and heated in the out<
flame of a Bimsen burner. The alkali double chloridesj
with iridous chloride, (IrCI,), are in general soluble in water.
Solutions of iriditim salts in the lowest condition of oxida-
tion give with potassium hydroxide a greenish precipita'
which tends to darken when boiled. Reducing agents,
as sodium formate, precipitate metalhc iridium, and hyd]
gen sulphide precipitates from the warmed solution a broi
iridium sulphide (IrS). By means of oxidizing agentaj
solutions of iridous salts may be converted into the high-
est condition of oxidation. From solutions of this latl
type potassitim hydroxide throws down a dark-brown prf
cipitate of potassium -iridium chloride, (IrCl,-2KCl).
hydrogen sulphide precipitates slowly a brown sulphidi
(IrjSj). The greater number of iridium compoimds
easily reduced by hydrogen on being heated. The

I
i

I
I

THE PLATINUM METALS.

•37

ence of iridium may be detected by the blue color de-
veloped when the compound is heated with concentrated
sulphuric acid to which ammonium nitrate has been added.

IV. Rhodium. Although three oxides of rhodium are
known and described, (RhO; RhjOji RhOj), salts of only
two conditions of oxidation are generally found; of these
the di- and trichlorides are types, (RhClj; RhjCiJ. From
solutions of rhodiimi salts reducing agents precipitate the
metal. Hydrogen sulphide throws down from a cold solu-
tion the sulphide (Rh,Sj), and from a hot solution the
sulphydrate {Rhj(SH)„). The insolubility of the double
chloride of rhodium and sodium, (Rh,Cr6NaCl), in water,
and of the double nitrate of rhodium and potassium,
(KoRho(NO]},5), in alcohol is made use of in separating the
metal from the other members of the group. Rhodiiun
is detected in the presence of the other platinum metals by
the yeUow solution obtained after fusion with potassium
acid sulphate and the change of color to red upon the ap-
plication of hydrochloric acid.

V. Ruthenium. In the variety of conditions of oxida-
tion in which they are fouijd, the compounds of ruthenium
resemble those of osmium. The lowest three oxides are
basic in character, (RuO; Ru,Oj; RuO,}, and form salts of
which the three chlorides, (RuCl, ; RUjCl^ ; RuCl,),are typical.
The trioxide, (RuO,), is known only in combination, where

it acts as an acid and forms salts of the type R^RuO,.
Another oxide, (RujO,), known only in combination, forms

salts represented by the fonnula RRuO^. The tetroxide
(RuOJ is volatile and similar to the corresponding oxide of
osmium in its chemical behavior; it has a characteristic
odor. A solution of the trichloride, (RujCla), throws out,
when heated, a dark precipitate which is generally sup-
posed to be an oxychloride; this precipitate is held in ,
suspension in the liquid and gives a pronounced coloration, f

as* THE R/tRER ELEMENTS.

even in very dilute solutions. Hydrogen sulphide, acting
upon solutions of ruthenium salts, precipitates a mixture
of sulphides, oxysulphides, and sulphur; this mixture is
brown or black, and may contain one or more of the sul-
phides RujS,, RuS^, and RuS,.

Estimation. The platinum metals are weighed in the
elementary condition, obtained as described under Prepara-
tion of the various metals.

Osmium may be determined volumetrically by causing
potassium iodide to act upon the tetroxide in the presence
of dilute sulphuric acid, {OSO. + 4KI + 2H,SO. = OsO,+
2K,S04 + 4l + aHjO), and estimating by means of sodium
thiosulphate the iodine thus liberated {Klobbie, Chem.
Central-Blatt (1898) 11, 65 (abstract).,

Separation. The separation of the platinum metals
has been considered under Platinum. The following are
additional references; Gibbs, Amer, Jour. Sci. [2] xxxi, 63;
XXXIV, 341; xxxvii, 57; Forster, Zeitsch. anal. Chem.
V, 117; Bimsen, Liebig Annal. cxlvi, 265; Chem, News
XXI, 39; Deville and Debray, Compt. rend, lxxxvii, 441;
Chem. News xxxviii, 188; Wilm, Ber, Dtsch. chem. Ges.
XVI, 1524; Leidie, Compt. rend, cxxxi, 888; Bull. Soc.
Chim. d. Paris [3] xxvii, 179.

EXPERIMENTAL WORK ON THE PLATINUM

METALS.*

Experiment 135, Precipitation of palladious iodide,
(Pdlj). To a solution of a palladium salt add a little
potassium iodide in solution.

Experiment 136. Precipitation of palladious sulphide, J
(PdS). fa) Pass hydrogen sulphide through a solution of.j
a palladious salt.

*For experimental wort on platinum see page 129.

I
I

EXPERIMENTAL fVORK ON THE PLATINUM METALS. I39

(6) Try the action of ammonitim sulphide upon a palla-
dious salt in solution.

Experiment 137. Precipitation of elementary palladium.
To a solution of a palladium salt add sodium carbonate
to alkaline reaction; add also a few drops of alcohol and
boil.

Experiment 138. Action of nitric acid upon palladium.
Try the action of nitric acid upon a small piece of metallic
. palladiiun.

Experiment 139. Precipitation of osmium sulphide,
(OsS^). (a) To a solution of osmium tetroxide acidified
with hydrochloric acid add a little hydrogen sulphide.

(6) Try the action of ammonium sulphide upon the
tetroxide in solution.

Experiment 140. Formation of potassium osmate,
(K2OSO4). To a solution of osmium tetroxide add a solu-
tion of potassium hydroxide. Note the yellow color.

Experiment 141. Action of reducing agents upon osmium
tetroxide. Try the action of an alkali sulphite, formic acid,
and tannic acid, respectively, upon a solution of osmium
tetroxide.

Experiment 142. Action of osmium tetroxide upon hy-
driodic acid. To a solution of osmium tetroxide add a little
starch paste and a small crystal of potassium iodide. Acid-
ify the solution with dilute sulphuric acid. Note the blue
color, due to free iodine.

Experiment 143. Precipitation of elementary osmium,
(a) To a solution of the tetroxide add stannous chloride.

(6) Try the action of zinc and hydrochloric acid upon
a solution of the tetroxide.

Experiment 144. Odor test for osmium. Warm a dilute
solution of osmium tetroxide, or warm with nitric acid a
solution of any osmium salt of the lower condition of
oxidation. Note the odor.

Experiment 145. Precipitation of iridium sulphide ,

14©

THE RARER ELEMENTS.

(Ir,S,). Pass hydrogen sulphide through a solution of
iridium tetrachloride. Try the action of ammoniuin sul-
phide upon the precipitate.

Experiment 146. Formation of the double chlorides of
iridium with ammonium and potassium, ((NH,),IrClj and
KjIrCla). To separate portions of a fairiy concentrated
solution of iridium tetrachloride add ammonium chloride
and potassium chloride respectively.

Experiment 147. Reduction of iridium salts, (a) To a
solution of iridium tetrachloride add oxalic acid.

(fe) Try similarly the action of zinc upon an acid solu-
tion of the salt.

Experiment 1 48. Action of sodium hydroxide upon
iridium tetrachloride. Add sodium hydroxide in excess
to iridium tetrachloride and warm. Note the change in
color. The iridium salt is said to be reduced to the tri-
chloride by this treatment. Acidify with hydrochloric
acid and add potassium chloride. Note the absence o£ ■
precipitation. I

Experiment 149. Precipitation of rhodium sulphide,
(RhjS,). Pass hydrogen sulphide through a solution of
sodium-rhodium chloride. Try the action of ammonium
sulphide upon the sulphide precipitated.

Experiment 150. Reduction of rhodium salts. To an
acid solution of a rhodium salt add zinc.

Experiment 151. Formation of the double nitrite of potas-
sium and rhodium, (K,Rh{NO,)fl). To a solution of sodium-
rhodium chloride add potassium nitrite in solution and
warm. Try the action of hydrochloric acid upon . the
precipitate.

Experiment 152. Precipitation of rhodium hydroxide,
(Rh(OH),). Note the first action and the action in exces
of sodium or potassium hydroxide upon a solution of sodium-^j
rhodium chloride. Boil the solution just obtained.

Experiment 153. Precipitation of ruthenium sulphio

GOLD. 141

(RujSg). (a) To a solution of ruthenium trichloride add
hydrogen sulphide.

(6) Use ammonium sulphide as the precipitant.

Experiment 154. Formation of the soluble double nitrite
of ruthenium and potassium, (K3Ru(N02)6). To a solution
of ruthenium trichloride add a solution of potassitim nitrite.
Note the color. Add ammonium sulphide to the solution.

Experiment 155. Precipitation of ruthenium hydroxide^
(Ru(0H)3). To a solution of ruthenium trichloride add
sodium or potassium hydroxide in solution.

Experiment 156. Precipitation of metallic ruthenium.
To an acid solution of a ruthenium salt add metallic zinc.

GOLD, Au, 197.2.

Discovery. Gold is probably one of the earliest known
of the metals. In very ancient records frequent mention
is made of its uses. As far back as 3600 b.c. in the Egyp-
tian code of Menes a ratio of value between gold and silver
(2.5:1) is mentioned. Rock carvings of Upper Egypt
dating from 2500 b.c. show crude representations of the
washing of gold-bearing sands in stone basins, and of the
melting of the metal in simple furnaces by means of mouth
blowpipes. In fact the discovery of gold dates back to
the beginnings of civilization. The search for it furnished
the motive of many voyages of discovery and conquest,
which restdted in the extension of civilization; and from
the desire to change the base metals into gold sprang the
study of alchemy, from which developed the science of
chemistry.

Occurrence. Qold occurs in nature both free and in
combination. Free or native gold is found (i) as vein
gold, in the quartz veins which intersect metamorphic
rocks, and (2) as placer gold, generally in the form of grains
or nuggets, in alluvial deposits of streams. Native gold is.

142 THE RARER ELEMENTS.

usually alloyed with silver, which sometimes amounts to as
much as fifteen per cent, of the alloy. Iron and copper
are sometimes present, and bismuth, palladiimi, and rho-
diimi alloys are known.

In combination gold is found as follows:

Petzite, (AgAu)2Te, contains 18-24% Au

Sylvanite, (AuAg)Te2,
Goldschmidtite, AtLjAgTec,
Krennerite, (Au,Ag)Te2-AuTe2,
Calaverite, (Au,Ag Te2-AuTe2,
Kalgoorlite, HgAu2AgeTefl,
Nagyagite, AUjPb^.SbgTe^Si^,

26-29%

31-32%
30-34%
38-42%
20-21%

5-12%

<<

ic
(I
(I

Extraction. The six processes indicated below follow
the principal methods that have been employed for the
extraction of gold.

(i) Washing or Hydraulicking, This method is applied
mainly to placer deposits. Powerful jets of water are
directed upon the gold-bearing sands, causing them to
pass through a series of sluices. Because of its higher
specific gravity the gold is largely left behind, . while the
other materials are carried away.

(2) Amalgamation (primitive). In this process the
crushed ore or the gold-bearing sand is first washed, to
remove the greater part of the light, worthless material,
and the remainder is rubbed with mercury in a mortar.
The amalgam thus obtained is heated, whereupon the
mercury is volatilized and the gold remains.

(3) Stamp battery amalgamation. The ore is pulverized
and mixed with water, and in the form of pulp caused to
pass over a series of amalgamated copper plates. Gold
amalgam forms on the plates, and from time to time it is
removed and cupelled.

(4) Chlorination. (a) Vat process. The crushed ore
is placed loosely in large vats and moistened with water.

GOLD, 143

Chlorine is forced in, and the whole is allowed to stand for
about twenty-fotir hours. The material is then leached
with water tmtil the washings give no further test for gold.
The solution of gold chloride thus obtained is treated with
stdphur dioxide, to destroy the excess of chlorine, and then
with hydrogen sulphide. The gold sulphide thus precipi-
tated is decomposed with borax and the gold is melted
into bullion.

(6) Barrel process. Into large barrels are put water
and sulphuric acid, the ore, and chloride of lime. The
barrels are then closed and rotated for a period varying from
one hour to four hours. At the end of that time the con-
tents are leached and the gold is extracted as described
above.

The chlorination process is generally applied to low-
grade ores, and these must have been roasted unless the
gold occurs in them native.

(s) Cyanide process. The ore, grotmd fine, is placed
in large vats, and a dilute solution (.2-. 5%) of potassium
cyanide is forced in. After a time the solution is drawn off
and passed over zinc shavings, upon which the gold is de-
posited as a black slime. The mixture of zinc and gold
is either treated with sulphuric acid, to dissolve the zinc, or
roasted with a fltix of niter and carbonate of soda. The
reactions which take place in the cyanide process may be
represented as follows:

(i) 4AU + 8KCN + O2 + 2H2O = 4KAu(CN)2 + 4KOH.

(2) 2KAu(CN)3 + 2Zn + 2H20 =

2KOH + H, + 2Zn(CN)2 + 2Au.

(6) Smelting. In smelting the gold ore is mixed with
some other metallic ore appropriately chosen, and the
mixture is subjected to intense heat. The gold alloys
with the other metal, and the alloy is separated from the
residue, or slag, and worked for gold. Three modifications

144

THE RARER ELEMENTS.

of this important process are in common use, viz., lead^
copper matte, and iron matte smelting. The process of
lead-smelting is in outline as follows: The alloy obtained
by heating a mixture of gold and lead ores is melted with
zinc. The gold and silver combine with the zinc and rise
to the surface, leaving the lead below. The alloy of gold,
silver, and zinc is then skimmed off and roasted. The zinc
passes off, leaving the gold and silver, which are separated
by electrolysis.

The Element. A, Preparation, As extracted from its
ores gold is in the elementary condition {vid. Extraction).

B, Properties. Of a characteristic yellow color, gold
is the most malleable and ductile of the metals. It is about
as soft as silver. It is insoluble in acids, but is attacked by »
aqua regia, chlorine, bromine, and potassiimi cyanide. Its
melting-point is 1037° C, — ^just above that of copper. Gold
alloys with nearly all the metals. It is occasionally fotmd
crystallized in the cubic system. It is a good conductor
of heat and electricity. Its specific gravity is 19.49.

Compounds. A. Typical forms. The following com-
pounds of gold may be considered typical forms:

Oxides AujO

AujO,

AU3O3

Hydroxide

Au(OH),

Chlorides AuCl

AU3CI4

AuCl,

Double chlorides,

I

many of the types

AuClj.RCl
AuClj.RCl,

Bromides AuBr

AujBr^

AuBrj

Double bromides,

I

of the type

AuBr,RBr

Iodides Aul

Aula

Double iodides, of

I

the type

AUI3.RI

Sulphides AujS

AuA

AuA

2AU2S3-5Ag3S

Double sulphides . . AujS • NajS

2Au2S3-3MoSa

^

•

AuaSj-sMoS*

COLD, 145

Sulphites (double) AujSOj • 3Na2S08+ 3H3O Au2(S08)3 • 5K2SO,+ 5H,0

Sulphates AuSO^ AujCSOOs- K2SO4

Nitrate AuCNOa),- HNO,

Cyanides AuCN Au(CN)3

Double cyanides. . AuCN • KCN Au(CN)3 • KCN, etc

Sulphocyanides. . . AuCNS • KCNS Au(CNS) j • KCNS

B, Characteristics, The compounds of gold are known
chiefly in two conditions of oxidation, of which atirous
oxide, (AUjO), and auric oxide, (AUjOg), serve as types.
When metalKc gold is dissolved in aqua regia auric
chloride is formed, a yellow crystalline salt soluble in
water; when auric chloride is heated to 180° C. it goes
over to aureus chloride, a white powder insoluble in
water. The aureus salts resemble the salts of silver
and of copper in the cuprous condition; the auric salts
resemble those of aluminum and of iron in the ferric
condition. The auric hydroxide, (Au(0H)3), is acidic
in character and tuiites with bases to form aurates of the

Is

type RAuOj. Hydrogen sulphide precipitates browmsh-
black auric sulphide, (AujSg or AUjSj + S), from cold solu-
tions of gold salts, and steel-gray aureus sulphide, (AU2S or
AUjS + S), from hot solutions. Salts of gold in solution
are easily reduced to the metal by reducing agents.

Estimation. A. Gravimetric, Gold is weighed as the
metal. From solutions it is precipitated by reducing agents,
such as ferrous sulphate, oxalic acid, formaldehyde, and
hydrogen dioxide in alkaline solution.

B, Volumetric, Gold may be determined volumetrically
(i) by allowing potassium iodide to act upon auric chloride,
(AuCl3 + 3KI=3KCl + AuI + l2), and estimating the iodine
thus freed by means of thiosulphate (Peterson, Zeitsch.
anorg. Chem. xix, 63; Gooch and Morley, Amer. Jour.
Sci. [4] VIII, 261; Maxson, Amer. Jour. Sci. [4] xvi); (2)
by warming a solution of auric chloride with a measured
amotuit of arsenious acid solution which must be in ex-

146 THE RARER ELEMENTS.

cess, (3As203 + 4AuCl3 + 6H20=3As,0.+ i2HCl + 4Au), and
determining the excess of arsenious acid by iodine in
the usual way (Rupp, Ber. Dtsch. chem. Ges. xxxv, 201 1;
Maxson, loc. cit.).

Separation. Grold and platintim fall into the analyt-
ical group of arsenic, antimony, and tin. From these
they may be separated by the following process: fusion
of the sulphides with sodium carbonate and niter, and
removal of the arsenic by extraction with water ; treatment
of the insoluble residue with zinc and hydrochloric acid,
which reduces the tin and antimony to the metallic con-
dition; boiling with hydrochloric acid, which dissolves the
tin; then with .nitric and tartaric acids, which dissolves
the antimony, leaving gold and platinum.

For the separation of gold from platinum and the plat-
inum metals vid. Platinum.

EXPERIMENTAL WORK ON GOLD.

Experiment 157. Extraction of gold from its ores, (a)
Digest for several hours in a beaker on a steam-bath about
100 grm. of finely ground gold ore with a dilute solution of
potassium cyanide, adding water from time to time to re-
place the liqtiid evaporated. Filter, pass the filtrate several
times through a funnel containing zinc shavings, until upon
testing the liquid with a fresh piece of zinc no discoloration
of the metal is observed. Dissolve the zinc in hydrochloric
acid to remove the black deposit. Filter, dissolve the resi-
due in aqua regia, remove the excess of acid by evaporation,
and test for gold by stannous chloride, ferrous sulphate, etc.

(6) Mix in a glass-stoppered bottle about 100 grm. of
finely ground ** oxidized*' or previously roasted ore with a
little bleaching salt and enough water to give the mass the
consistency of thin paste. Then add gradually enough
sulphuric acid to start an evolution of chlorine. Close the

EXPERIMENTAL IVORK ON GOLD, 147

1x)ttle and shake it, to instire a thorough mixing of the
contents. Allow the action to go on for several hours, agitat-
ing the mass occasionally, and taking care to have an excess
of chlorine present throughout the process. ' Extract with
water, concentrate if necessary, and test for gold in the
solution. A two per cent, solution of bromine may be
substituted for the materials generating chlorine.

Experiment 158. Precipitation of the sulphide of gold,
(AujSa or AU3S2 + S ?) . Into a cold solution of auric chloride
pass hydrogen sulphide. Try the action of yellow am-
monium sulphide upon the precipitate.

Experiment 159. Formation of aurous iodide, (AuT).
To a solution of auric chloride add a few drops of a dilute
solution of potassium iodide. Note the precipitate, and
the solvent action of an excess of the reagent.

Experiment 160. Formation of ammonia aurate, ** ful-
minating gold,^^ ((NH8)2Au203). To a very dilute solution
of a salt of gold add a little ammonium hydroxide.

Caution. Do not attempt to isolate the precipitate.
Note that neither potassium nor sodium hydroxide gives
a precipitate under similar conditions of dilution.

Experiment 161. Formation of the "purple of Cassius,''
To a very dilute solution of a gold salt add a drop or two
of dilute stannous chloride solution.

Experiment 162. Precipitation of gold. To separate
portions of a solution of a gold salt add ferrous sulphate
and oxalic acid in solution. Observe the color by trans-
mitted light.

Experiment 163. Solvent action of certain reagents upon
gold. Try separately upon metallic gold the action of
aqua regia. chlorine or bromine water, and a dilute solution
of potassitmi cyanide.

THE RARER ELEMENTS.

THE NEWLY DISCOVERED GASES OF THE
ATMOSPHERE.

Argon, A, 39.9
Helium, He, 4

Krypton, Kr, 81.8
Neon, Ne, 20

Xenon, X, 128

Discovery. In 1892 Lord Rayleigh, while ■
the study of the density of elementary gases, made the im-
portant observation that the nitrogen obtained from nitric
acid or ammonia was about one half of one per cent. lighter
than atmospheric nitrogen (Proc. Royal Soc. LV, 340).
An investigation of this difference led to the discovery
two years later of the gas Argon {apyos, inert) by Lord
Rayleigh and Professor William Ramsay (Proc. Royal
Soc. Lvn, 265; Amer. Chem. Jour, xvii, 225). An experi-
ment made by Cavendish in 1 785 seems also to have resulted
in the separation of this gas (Phil. Trans, Roy. Soc. (1785)
Lxxv, 372, and (1788) lxxviii, 271).

In the course of analytical work on uraninite undertaken
by Hillebrand in 1888, a gas which he thought to be nitro-

; gen was obtained upon the boiling of the mineral with dilute
sulphuric acid (Bull. U. S. Geol. Sur. No. 78, p. 43; Amer.

[ Jour. Sci. [3] XL, 384). In 1895 Ramsay, whose attention
had been called to Hillebrand 's work, and who doubted
whether nitrogen could be obtained by the method de-
scribed, prepared some of the gas by Hillebrand 's process
from cleveite, a variety of uraninite. He then sparked the
gas with oxygen over soda to remove the nitrogen. Ob-
serving very little contraction, he removed the excess of
oxygen by absorption with potassiimi pyrogallate and
examined the residual gas spectroscopicaUy. The spec-
trum showed argon and hydrogen lines, and in addition a
brilliant yellow line, (D,), coincident with the helium Kne

THE NEIVLY DISCOVERED GUISES OF THE yiTMOSPHERE.

of the solar chromosphere discovered by Lockyer in 1868
(Proc. Royal Soc. lviii, 6g, 81). The only previous note
regarding helium as a terrestrial element is a statement
by Palmieri, in 1881, that a substance ejected from Vesu-
vius showed the line D3 (Rend. Ace. di Napoli xx, 233);
he failed to describe his treatment of the material, how-
ever, and he seems to have made no further investigation of
the subject. Kayser first detected helium in the atmos-
phere, in 189s (Chem. News lxxii, 89), several months
after Ramsay's discovery.

The year i8g8 witnessed the discovery by Ramsay and
Travers of three other inert atmospheric gases. Having
allowed all but one seventy-fifth of a given amount of
liquid air to evaporate, and having removed the oxygen
and nitrogen remaining by sparking over soda, they ob-
tained a small amount of a gas which, while showing a feeble
spectrum of argon, gave new lines as well. This newly
discovered gas they named Krypton, from KpvnTos, hid-
den (Proc. Royal Soc. lxiii, 405).

By fractioning the residue after the evaporation of a
large amount of liquid air they found evidence of a gas of
greater density than krypton, and for this heavy gaseous
element the name Xenon (£evo?, stranger) was chosen
(Chem. News lxxviii, 154).

The third discovery of the year by the same investigators
was that of Neon {veoi, new), a gas of less density than
argon. The first fraction obtained from the evaporation
■of Hquid air was mixed with oxygen and sparked over
soda, and the excess of oxygen was removed by phosphorus.
The remaining gas yielded a new and characteristic spectrum
(Proc. Royal Soc. lxiii, 437).

Occurrence. Argon forms about one per cent, of the air
by volume. It is found in small quantities in gases from
certain mineral springs, e.g. Bath, Cauterets, Wildbad,
Voslau, the sulphur spring of Harrogate; also in the gases

THE RARER ELEMENTS.

f' occluded in rock salt. It has been detected in some heliuna-
[ bearing minerals, e.g. cleveite, broggerite, uraninite, and
[ malacon.

Helium, the existence of which was first observed in
I the sun, occurs in very small proportion in the terrestrial
1 atmosphere. The chief sources of the gas have been certain
I rare minerals, among which are uraninite (pitch-blende),
I cleveite, monazite, fei^sonite, samarsldte, columbite, and
T malacon. It has been found also in some mineral springs,
I e.g. Bath, Cauterets, and Adano, near Padua.

The other gases of this group are present in the air in
\ very minute quantities. Neon is said to constitute 0.0025%.
I and krypton 0.00002% of the atmosphere. Traces of neon
have been detected in the helium from the springs of Bath.
Extraction. Argon, contaminated with a greater or less-
percentage of the associated gases, may be extracted by the
I following methods:

(i) From atmospheric nitrogen. The nitrogen is passed
r over red-hot magnesium filings ; a nitride is thus formed,
L while the argon is left uncombined (Ramsay). Heated
[ lithiiun may be substituted for magnesium.

(2) From air. Induction sparks are passed through a

mixture of oxygen and air contained in a vessel which is

inverted over caustic potash. The oxygen and nitrogen

L combine and dissolve in the potassium hydroxide, leaving

f the ai^on (Rayleigh).

Helium may be obtained from its mineral sources by
boiling the material with dilute sulphimc acid, or by heat-
ing in vacuo.

Krypton and xenon are extracted as follows: After

I the evaporation of a large amount of liquid air the residue

is freed from oxygen and nitrogen and liquefied by the

immersion of the containing vessel in liquid air. The

greater part of the argon can be removed as soon as the

f temperature rises. By repetitions of this process the

, THE NEIVLY DISCOVERED GASES OF THE ATMOSPHERE. 151

three gases can be separated from one another, krypton
exercising much greater vapor pressiire than xenon at the
temperature of boiling air (Ramsay and Travers, Proc.
Royal Soc. lxvii, 330).

Neon is obtained from the gas, largely nitrogen, that
first evaporates from liqtiid air. This gas is liquefied, and
a current of air is blown through it. The material that
first evaporates is passed over red-hot copper, to remove
the oxygen, and after being freed from nitrogen in the
usual manner, is liquefied. By fractional distillation helium
and neon are removed, and argon is left behind. By the
use of liquefied hydrogen helium and neon are separated,
as neon is liquefied or solidified at the temperature of boil-
ing hydrogen, while helium remains gaseous. Several
fractionations are necessary to obtain pure neon (Ramsay
and Travers, Proc. Royal Soc. lxvii, 330).

Properties. The newly discovered constituents of the
atmosphere are inert, colorless, probably monatomic gases,
which have not been known to form definite compotmds.

Argon is somewhat soluble * in water. Its density is
19.96 and its specific heat 1.645. I^ solidifies at — 191° C,
melts at — 189.5° C, ^^d boils at — i85°C. Argon gives
two distinct spectra, according to the strength of the in-
duction current employed and the degree of exhaustion in
the tube. When the pressure of the argon is 3 mm. the
discharge is orange-red and the spectrum shows two par-
tictdarly prominent red lines. If the pressure is further
reduced, and a Ley den jar is intercalated in the circuit,
the discharge becomes steel-blue and the spectrum shows
a different set of lines (Crookes, Amer. Chem. Jour, xvii,

251).

Helium is slightly soluble t in water. Its density is
1 .98. Its spectrum is characterized by five brilliant lines, —

* 100 volumes of water will dissolve 3.7 volumes of argon at 20° C.

t 100 volumes of water will dissolve about 1.4 voltunes of helium at 20* C

JS« THE RARER ELEMENTS.

one each in the red, yellow, blue-green, blue, and violet, i
Reference has already been made to the yellow line Dj.

Krypton is less volatile than argon. Its density is i
40.78. Its spectrum is characterized by a bright line in theJ
yellow and one in the green.

Xenon also is less volatile than argon, and it has ai
much higher boiling-point. Its density is 64. Its spectrum
is similar in character to that of argon, though the position
of the lines is different. With the ordinary discharge the J
glow in the tube is blue and the spectrum shows three red I
and about five brilliant blue lines. With the jar and I
spark-gap the glow changes to green and the spectrum is 1
characterized by four green lines (Ramsay and Travers,
Chem. News Lxxvin, 155).

Neon is more volatile than argon. Its density is 9.96. j
Its spectrum is characterized by bright lines In the red,
orange, and yellow, and faint lines in the blue and violet.

RECENT UNCONFIRMED DISCOVERIES.

In September, i8g6, Barrifere announced the discovei
in monazite sands of an unknown element which differed*
from the members of the cerium group and from thoriunin
and zirconium in forming no double sulphate with either
sodium or potassium sulphate, and from the members of '
the yttrium group in being precipitable by sodium thio-
sulphate. He gave as the approximate atomic weight
of the element 104, and proposed for it the name Lucium
(Chem. News lxxiv, 159). A few weeks later Crookes
examined some of Barri^re's material, and declared lucium
to be yttrium with some admixture of erbium, didymium,
and ytterbium (Chem. News lxxiv, 259). The following 1
year Shapleigh confirmed Crookes's results, and pointed 1
out the weak places in Barrifere's deductions (Chem. News. 1
LXXVl, 41).

RECENT UNCONFIRMED DISCOVERIES. iS3

In 1897 Chruschtschoff called attention to a new member
of the didymiuni group which he distingiiished from praseo-
and neodymium by the blue color of its salts. The spec-
trum was in part that of neodymium. He suggested the
name Glaukodymium (yXavKoSy blue-gray) (Jour. Rus.
Phys. Chem. Soc. xxix, 206). Although it is considered
qmte possible that praseo- and neodymium are not simple
bodies, no confirmation of Chruschtschoff 's discovery has
appeared.

Nasini, Anderlini, and Salvadori, in 1898, discovered
in the spectra of gases from the Solfatara di Pozzuoli and
the fumaroles of Vesuvius a line (1474 K) of the corona
never before observed in terrestrial matter. They called
the unknown gas the presence of which was thus indicated
Coronium (Atti R. Accad. dei Lincei, Roma [5] vii, II, 73;
Amer. Chem. Jour, xx, 698).

The same year Brush, while studying the relation of
pressure to the heat conductivity of gases, extracted from
glass a gaseous substance which seemed to be different
from all known gases. He concluded that its heat con-
ductivity was 100 if H = I ; its density, also referred to hy-
drogen as the standard, was 0.0001, and its molecular
weight 0.0002. He suggested that it might be the ether
of the physicist, and proposed for it the name Etherion
(Amer. Chem. Jour, xx, 873; Chem. News lxxviii, 197).
Crookes, upon examination of the evidence given by Brush,
pronounced the gas probably water vapor (Chem. News
LXXVIII, 221).

About the time that Ramsay and Travers announced
the discovery of krypton and neon in 1898, they first
mentioned Metargon (Proc. Royal Soc. lxiii. 437). It
was obtained in the liquefaction of large quantities of argon,
remaining in the form of a white solid after the liquid
had largely boiled away. The gas obtained from this
solid had a density close to that of argon; its spectrum

.154 THE RARER ELEMENTS.

resembled that of argon and also that of carbon. Two
years later the same investigators announced that this
gas was merely argon mixed with some compounds of car-
bon (Proc. Royal Soc. lxvii, 329).

Crookes, in 1899, stated that as the result of a long
series of fractional fusions, crystallizations, and precipi-
tations of salts obtained from yttrium earth, he had dis-
covered an element which he had named Monium. A little
later, in recognition of the Queen 's jubilee, he changed the
name to Victorium (Proc. Royal Soc. lxv, 237). The
new element was described by him as having a pale-brown
color, as being less basic than yttrium, as being easily
soluble in acids, and as forming with potassium sulphate
a double sulphate less soluble than the corresponding
salt of yttrium, and more soluble than the corresponding
salts of the cerium group. Assuming the oxide to be
VC2O3, he calculated the atomic weight as 117.

Previous to 1898 the presence of ** radiant matter"
in uranium and thorium minerals, particularly in pitch-
blende, had frequently been noticed, and investigations
of the phenomenon had been carried on. It is not yet
fully determined whether the actinism is due to the pres-
ence in these minerals of certain elements having distinct
radioactive properties, though three substances possessing
this quality, and differing in other characteristics, have
been isolated and described as compounds of newly dis-
covered elements. In 1898 P. and C. Curie announced
the discovery in pitch-blende of Polonium {Polonia^
'Poland), and the next year, together with Bemont, of
another element. Radium* (Compt. rend, cxxvii, 175,
12 1 5). Also in 1899 Debieme named Actinium as a third
radioactive element (Compt. rend, cxxx, 906).

* Recent work on this interesting substance has led many chemists to
assign radium a place among the elements. See Mme. Curie, Compt. rend,
cxxxv, 161; Runge and Precht, Annal. der Phys. u. Chem. [4] x, 655;
Hammer, Chem. News i^xxxvii, 25.

RECENT UNCONFIRMED DISCOVERIES. 15 5

In the summer of 1901 Baskerville described some
work on pure thoriimi salts which had suggested to him
the probable existence of an xmknown element associated
with thorium. He found it possible, by fractioning pure
thorium dioxide, to obtain two oxides of specific gravity
9 25 and 10.53 respectively. Radioactivity increased with
specific gravity, the oxide of lower specific gravity being
practically inactive. A determination of the atomic weight
of thorium from the pure tetrachloride gave 223.25, as
against 232.5, the generally accepted value. The probable
atomic weight of the new element was given as between
260 and 280, and the name proposed for it was Carolinium,
because the thorium salts were prepared from the monazite
sands of the Carolinas (Jour. Amer. Chem. Soc. xxiii, 761).

INDEX.

PAOB

Actinium 154

Argon. 148

Beryllium 16

Caesium i

Carolinium « 155

Cerium 30

Columbium 65

Coronium i 153

Decipium 27

Didymium 36

Dysprosium 27

Erbium •• 27

Erythronium • • 84

Etherion 153

Gadolinium 27

Gallium 75

Germanium 55

Glaukodymium 153

Glucinum 16

Gold 141

Helium 149

Holmium 27

Indium .* 72

Iridium ^ 130

Kr3rpton 149

Lanthanum 36

Lithium 11

Lucium.* 152

Menachite 58

Metargon 153

Molybdenum 91

Monium 154

Neodymium •• 36

PAOB

Neon , 149

Niobium • 65

Ochroite 30

Osmium 130

Palladium ••. 130

Philippium. 27

Platinum 122

Pluranium 131

Polinium 131

Polonium 154

Praseodymium • 36

Radium 154

Rhodium 130

Rubidium • 5

Ruthenium. 130

Samarium 27

Scandium 27

Selenium • 114

Tantalum 65

Tellurium 107

Terbium 27

Thallium 78

Thorium 44

Thulium 27

Titanium 58

Tungsten • 96

Uranium loi

Vanadium 84

Victorium 154

Xenon 149

Ytterbium. 27

Yttrium <... 20

Zirconium. 50

157

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1

Woodbury's Firs Protection of MlUl . . ,. Bto

The World-. ':olunibian E.positton of 1853 Large 4to

ARMY AHD HAVY.

Bernadou'. Srookeku Powder, Mitro-celluloie. and Iha Ibeory of the CUulow

• Davis's Elemenu of Law Sva

r:|

Sheep

.;s ™

t IS

<«

. I.

If. m

... 1

-: ■

J

I

• Wilke'g LentuiEB o

• Whcelei-i Sicee Ope
Wlnthrop'a Abridgmi
WoodhuU'i notes oD
Young's SiioplB Elemi

Secpnd Edition,

lions and ID^itarr Hlnini Btb, 3

9l HjUtary Law lamo. a

aury HTKlone iSmo, i

natcher'i Prsctical loBtmcti

ASSAYING.
in QuantiUIivo Ai

Farmao's Manual at Practical ABsaying 8vo, .

»lU«r'» Manual of Assaying ijmo,

O'DrlscoU'i Holes on tba Tlealment of Gold Ores Bto,

RicketCs and Uillei's Holes on Assayins Svo, .

Hike's ModeroElectrolytic Copper Refining Bvo, .

WilKa'i Cyanide Ptocosses lamo,

CUarinalion Procisa i2mD,

ASTROHOMY.

BOTAHY.
cat Hethads, with Special Referi

CHEMISTRY.

idlianca'slaboratory Calculations and Specific Gravity Tables. .ijn

Alien's Tables for Iron Analysis 8'

Arnold's Compendium of Cliemiatry. (llandeL) (lit jtreparation.)

Austen's notes for Chemical Students iin

Beniadou's SmokeleES Powder.— Hllco-celluloie, and Theory of the Ceiiuji

Molecule un

Bolton's Oua°<itative Analjsia 8'

* Browning's Introduction to tiie Rarer Clements , . , ,-.-.. .B'

Brush and Penfield's Manual of Detetminali^e Mineralogy S

Classen's OuantiUti»B Chemical Analjsia by Electrolysis. (Boltwood.) ,. 8
Cotm's IndicBIore and Teal-papers iin

Copeland-s Man
Craft's Short Co

Quhem's Therm
Eisaler's Mod en

lot B

(/i

Ui»n.)

'e Chemical Analysis. [Scbaefler.l. .

h

Se«d'i Top(^(r■p1llc■l Dnning and Sketchlas.
BidCBl'iSevagcaiid U» BsclirUl FariacatlDD o
Slabeil and Bisgin's Uodccn Stone-cuttlnt and
Smith's Hanuil of TopoEnphical Dctving. <
Ssnderlclur'i Gnphlc Statlci, vim AppUcsi

Aiches

• TiaiitwJoa's Civil Engiosei'i Pocket-book. . .
Wklt'i EnginieriOK BDd A

Uw of Operal

u Prellinliury to Coostructlon J

Wuren'B Stereotoi
Wcbb't Prohlemi

— Pioblemt In Stont-mlUoB. . .

pf EBguieBrlnf IzutrunwDti.

BRIDGES AND ROOFS.

Idler'* Practical TrutlM on the ComtructlDn of Hon BigtawkT BiidtM. .8va,

■ Tli«nwi RliM Bridge 410, pipei,

Bun'i Courie on the Streuci m Bridges and Boot TniiKi. Arched Ribs, and

Fowlet's CoHet-daca Pro
Onene's Root Trusaei . .

Brides Trussea....

Archoi ~"

Howe's Treatise on Arches Si

Design of SimplsRoof-tniisea in Wood aad Gteel Bro,

JalMuoa, Bryan, end Tumeaurs's Theory and Practice In the Dedguinc of
Uodern Framed Struclures Small 4to, 11

Utniiaaii and Jacoby's Teit-book on Roofs and Brldsn:

Part l.—Streseei In Simple Tnuees 8vo, !

Part n.— Graphic Statics 8to,

Part m.— Bridge Design. 4th BdlHoa, Rewritten Sto, :

Part IV.— Higher Structurei. 69a,

KorisDn'i Memphis Bridge 4ta. 1

Viddell'sDe Pontibus, a Pocket-book for Bridge Englneen., .tSmo, morocco, .
SpedflcBlloiu tor Sleel Bridges lamo,

Wood's Treatise on the Theory of the Construction of Bridges and RooIt.Sio, :

Vrighi'B Designing of Dtaw-epani:

Part 1, —Plate-girder Drawa Bvo,

Part IL— Rinted-trusi and Pin-connected Long-span Draws.
Two parts la one volume .

1 SO

1 SO
] SO

4 00

5 DO

a so

3 SO

3 SO

M

W Oui«um.t imd KuMar's GensfKl FarmuJa lot He Uniform Flow

f Water i

Sana's Filtration of Public Watcr-supplT

HBiKbel's Its E.petimiiaU on IheCsriTing Capacity otLaiBe.Ri

8to

eted, Mela

H.!oo's W.ler-aupply. (CooBidered Principally from > Sanitary Stand

tic Water
.Large 8vo
tionall. 4to

•• ThomB! ana Watt's Improvement of RiyerB. (Post., 44 c- "^il'

SmaU Svo

MATERIALS OP ETIGinEBRmG.

Oblaoe 4to

Burr's Elasticity and Rcslslaoc. of the »lal«riala of BagineBTiag. fiih Edi-

Inspection of the Materials and Workmanship Employed in C

n,tructmn

Small 4to
Large Btp

Uarte OS's Hand boob on TEsting materials. (Henning.) 1 vols Sio

Merriman'B Te.t-book on the Mechanics of Materials

8-"

SmaU 4to

7

■•cCord'i Elements of Deacriptivo GBonntrr

Kinematica; or, PracticBl MKh«nlnii.

Mecbanicsl Drawing

Velocity Diagranu....'

• Hahan's Descriptive Geomeby and Sloae-cuttine

Industrial Drawing. (Thompson.)

R«d's Topogiaphlcal Dra vine and Sketching

Kelil's Course in Mechanical Drawing 8to,

Tcit-book of Mechanical Drawing and ElemenUr; Uachiae Design '

nciplei

Qual of Topographical Drawing. (HcUlUan.) S

lements ot Plane and Solid Free-hand Geometrical Drawing. . i m

Drafting Inslrumeuta and Operations i:i

Haoual or Elementary Pro jectioQ Drawing lin

Manual ot Elementary Brobiemi in the Linear Penpeclive of Form a

Shadow - un

Plane Problema in Elementary Geometry ...,.-..,.i2d

Primary Geometry un

ElemeotB ot Deicriptive Geometry, Shadow!, and PerspectiTe 8'

General Problems of Shades and Shadovt B'

Elements ot Machine Conavaetion and Drawing S'

Problems. TheoremB, and Eiamples In Descriptive GeomelTV S'

Welsbach's Xinematica and the Power of Tranamiaaion. (Bermami a

Whelpley'e Practical Instruction Ic
Wilson's Topographic Surreylag. .

Plse-haDd PerspectiTe

Free-hand Lettering

WoolTs Elementary Cduieb in De!

al Loiter Eograylng , .

Anthony and Brack
Anthony's Lecture-i

Voltaic Cell..,.

ELECTRICITY AMD PHYSICS.

tfs Text-book of Physics. (Magie.)

Crahore and Sauier-e Poiai
Dawson's "EnEineerlng" and Elect
DolezalelCs Theory of the Lea

(Shon/j/.) (Von Ende.)
Dnhem's Thermodynamics and Chi
nather-sDni

■s De H
Haochett's Allen

(Motte

tE Explained.

Telescopic Mirror-scale Method, Adjui
Lannauer's Spectrum Analysis. (Tingle.)..
La Chatelier's High-temperature Meaaureme
LBb's ElecQ

mElecti

a Relalioi

Hiaudet's Elementary Treatise on Electric Ball
■ Parshall and Boban's Electric Generators. .
• Rosenberg's Electrical Engineering. (Halda
Kyan, Morris, and Hoiie'a Electrical Mschioer

s Stationary Steam-engiaet

's Elementary Lessons in Heat

IFishoBck.1...
imall 4to. half

Tor; and Pitcbei'i Hiaul of L«bD»tai7 Pbrtlu Small Sia, i

Ulka'f Modem Blecliolrtk Coppci ReflniDC 8to, i

LAW.

• DiTii'i Ekmeati of l*w 8vo, :

• Tratiie on the Uiliurr Lav of Dniteil Sum 8ni, ;

Haonal for CDiuO-mar^l itmn. oiaracco. i

Walt'i EofiBtttiat loi AtebitectuiBl Juriapruduiea 8to, I

Sheep. (
Law of OperatlDU PiellmiDHT to Conitructian in Encinteiini aod Aicbi-

Sheep, s !

Law of ContracM 8»o, 31

Wlnthrop'iAbridEtncatof HIlitarrLaw laraa, II

MAHOTACTURES.

Bernndou'i Smokeleu Powder— nitro-celluloH and ThioTj of Iht Cellulon

Molecule Ijnio, a !

Bo lland'i Iron Founder iimo, i )

"The Iron Founder," Sapplement IMDO, a ■

Encyclopedia of Fonndloc and SlcUonaiY of Foandij Tenni IJaed In Uu

PractlM of Houldinc una. 3 i

Eiuier'a Modem Hlth Biploslrea 9r«, 4 I

BffronfiEniTmeiandlhelrAppUcationa. <PrB«ott.) B»»i 3 I

PlIiterald'B Bolton Hichinlil ittao, i I

Foid-i Boiler Making for Boiler Usken iSmo, i 1

Eopkiui'i Oll-cbemlili' Handbook Sn>. S <

Keep'i C^aet Iron 8to, 1 i

Leacb'i The iDipectlon aad Anilyils at Food with Epecial Kafennc* M Stall ■

Control, (/nprepomlfon.)

Hetcall'a SleeL A Manual for Steel-uien lano, » 1

HetcaUe'i Coat of Haaufaclurei -And the Adminiatiation ol Vorkihopa,

Puhlie and PriTaie 8»o. g 1

Meyer'B Modem Locomotive Conitroetloii «to, 10 1

• Relaii'a Guide to Piece-dT*lng 8to, >| 1

Smltb't PrMS-worklog of Hetalt , S*0| 3 1

Wire : Ita Hae and Manufacture SmaH 410, 3 1

Spalding'i HTdraulic Cemgot lUBO, a^i

Spancer'a Handbook for Cbemiiti of Bect-sncar Hooaei lAiUD.moTOCBO, ti

HandbOD:< lor ausai Uanutacturen and their Chembta.. , i6me. morocco, 3 1
Tburaton'a Manual of Steam -boUera, tbeir Deaifni. Coniiruction and Oper>>-

• Walke'a Leeturea on Eiploaivea Bvo, 4 ■

HouUer'j Ten-book lamo, » '(

Wlechmano's Sucar Analysia SmiU 8*0, i'|

WdHTs Windmill » a Prime Mover 8»o, 3. *

Woodbury-s Fire Protection of MllH. Bm, w

MATHEMATICS.

Baker's Elliptic Functiona B»o, i

• Bau'a Elements of DiaeriDtiai CaJculna

BriBgs'a Element* of Plane Analytic Georaelry

10

Compton's Haaual ol Lataiithmic Comiulatloni , .

D«Ti»'i Intioductioo to Ihe Loeic ol AleebiB 8vo,

■DieksoD'i College Alsebra. Laigs i

* IntroducCion lo the Theory cf Alcsbnlc EqiutJoni Largs iimo,

Haliled's Elements of OeometiT

ElemenUfj Synthetic Geometry

Kitional Geometry. (Shortly.)

■ Johnioa's Thiee-place LotCBiithmlc Tablet: Veat-pockel ^e

* MouQted OD beSTT cardboard, B x ia i

Elementary Treatise an the Integral C^lcnliu Smi

Curve Tracing in CsrtesLan Co-ordinates

Treatise on Ordinary and Partial Differential Equadons Small Sro,

Theory of Errors and the

■ Theoretical Mechanics . .
Laplace's Philosophical Essay i

* Ludlow and Ban. Blemeul

Tables .Svo,

Trigonometry and Tables pullUBhed separately

Mauref's Technical Mechanics

Merrlman and Woodward's Higher Mathematics

Merriman's Method of J^asl Squares

Rice and Johnson's Elementary Tieatiso on the DiHerential Calculus 1
Differential and Integral Calculus. 3 vols. In one Z,

Wood's Eleraen* of Co-ordinate Geometry

Trigonometry: Analytical, Plane, and Spherical

MECHAHICAL EITGIHEEHnrG.

MATERIALS OF EUGIHEERUIG, STEAM-ENGIHEa ABD BOILERS.
Baldwin's Steam Heating for Buildings larao.

' ■• ■' " AbridgedEd.

Benjamin's Wrinkles and Reeipes

Sto,

Svo,

Treatise on Beits and Pokeys umo,

Ball's Csr lubriralion

Euit's Mechanical Engineer's Pockel-book

KacCord's KlnemaUci; or. Practical Mechaniim.

i6mo. motocco,
Svo.

Svo

k

Hahan-s lodujlrlal Drawing, (ThompfOIi.) 8to, 3 s»

PaolE'9 Calorific Power of Fuels 8vd, 3 M

Reld'i Caune in Mactunicel Drawing 8vo. ) oa

T«it-bDOk o( Mechanical DrBwias and EInnenlBry Uachinc DbsIcd . , 8vo, 3 00

Ricliards'i Campresud Air Iimo. I S*

4oblaioa'i Principles of Hechaaiim. Bto, 3 00

Scallh-iPnei-WDrklDeolHetali 8>d, 3 on

Thurston-e Trcaliaa on Fiictioa and Loat Work in Uacbinen u>d Mill

Animal as a Maelilae and Piime Molar, and the Laws of EcerEetici. iimo. i oo

Warres'lElementBor Uacliinc CooatructiDn and Diagriog . Sro. 7 50

WElBbach'i KJnematics and Ihe Power of TrarsmisBion. Hertmaui—

Klein.).. Bto, 5'aa

Macliinet; at TranusIaGioa and Goveraon. CHartmBjiU'-KIeIn.)"Svo, S M>

Hydraul.ca and Sydraulic Uotora. (Du Boia.) Sto, 5 oa

WolH'e Windmill ai a Prim* Hover. 8»0, 3 00

Wood'i TuibineB 8to. 1 SO

HATERULS OF ENGHTEEBinG.

flovey's Strength of Ma leriala and Theory nf Snutturei Bvo, 7 90

Bun'* ElasticltT and Resiaiance ol the MaUrials of Engineering. 6th Edition.

Cburch'a Mechenlci of Engineering Sto. 6 oa

Johnson'" Materiala of Conatnictlon .^arge StOb 6 00

Ceep's Caal Iron Sto, 3 so

Lanis'i Applied Hcctaanio Sro, 7 50

Martens'B Handbook on Tealing Materiala. (Hennlng.) 8to, 7 50

Kerriman'B Teit-book oa (be Machanica ol Materiali Sto, 4 00

Strength of Materals iimo, I 00

HelcalTi SteeL A UanotJ for Sleel-HBen lanw 1 o*

Smith's Wire : Its Dae and Mauuf letura Small 4I01 3 00

Hateriali of Machines . lamo 1 no

Thorslon') Hateriali of Engineering 3 Tola, Sto, 8 00

Part n.~I)oD and Sieel S»o, 350

Part m.— A Trealiaa on Brasaeij Broniea, and Other Allays sad their

Constilueals. , 8to * so

Tell-booli ol the Materials of ConstruclioD. Sto, 5 «0

Wood's Treatise on the RealBtance of Hateriali anc
PrcEervationof Timber

Elements of Analytical Mechanics

Wood's Rustless Coatings. (Sliortln.)

STEAM-EHGINES AHD BOILERS.

Carnot'sReSecHDnsonibeMotiTePDwcr of Heat. (Thurston.).
Dawson's "Engineering" and Electric Traction Pocket-book.

Ford's Boiler Making for Boiler Makers

Goss's Locornoiive Sparks

Bemenway's Indicator Practice and Steam-eagine Economy . . .
Button'! Mechanical Engineering of Pawei Planli

Kern's Stoaro-bO'ler Economy

Eneaas'a Practice and Theory of the Injector

MaeCord's Slide-valsos

Meyer's Modem LoeomotiTe Construction

12

I

Pe»bod7'« MiooBi of the Steam-enslne InJiealor

Tablw of the Properties of Satonterl Steam and Other Vapora

TbermiMlTnamiu of the Steam-eiiEliie and Other Heat-englnei . . .

Valre-KcaiB for Steam-enginee

Pealfody and Mlllei'i Steam-boikts 8vo,

Pray>a Twenty Yean with the Indicator Laree 81

Pnphi'B TbermodTBamica of ReTenlble Cyclei in Gaseg and Saturated VaiH

(Oeterl

dEleetric..

: Simple. Compotind, a
Roatgen's Principle! of Thermodynaloics. (l)u Uoia.). .
Sinclair's Locomotive Engine Rimning and Manageoient.
Smart^fi Handbook of En^ioeerins Laboratory Practice - .

■■ Stea

.-boiler Pracd

Spangler'g Valie-geara

Notes OD ThermodrnamicB- .

SpBQKlsr, Greene, and UaiahaU'i '.

Thnrjton's Handy Tablei 8vo.

Uanual of the Steam-engine ITok. 81

Part I.— Hiitory. Stmctuce, and Theory Bi

Partn,— Design, Coostructloo, and Operation Si

Bandboob of Engine and Boiler Trials, and the TTse of the Indicator a

the Prony Brake 81

Stationary StBOm-edEiaeB &•

Sleam-boiler Explosions in Theory and In Practice. ran

Uanual □( Steam-bailen , Their Designs, ConstTuction, and Operation . Sn,

Weisbaeh'a Heal, Steam, a d Steam-engines. (I>n Bois.)

Whitliam'e Sleam-enghie I esign

Wilson's TrestiM on Steam- bo ilerfl. (FUlher.)

Wood's Thermo djuamicB. Heat Motors, and Refrigerating Machines.

UECEAinCS Ain> UACnmERY.

f Materials and Theory of Slructurea SvOi

.nrch'a Mechanics of Engineering

Notes and Eiamples In Mechanics. .

Compton and De Groodt*! The Speed Latht
Cromwell's Treatise gn Toothed Gearing. .

DaoH's Teit-book ol ElemenUr; Mechai
Schools

Dhigey's Uachinery Pattern

Dredge's Record of the Tn

Columbian Eipoiitioa ol tSga 4ta. half moroci

Dn Bois's Elementary Principles of Meilianics:

Vol I.— Kinematics 81

Vol n.— Statics Bi

Vol. m.— Kinetioi Si

Mechanic! of EDgineering. VoL I Small 4I1

1 EihibitB BnlldioE of the World'

in...

II 4to,

Fitzgerald's fiosloa HachiniBI. .

Flather'i DynamometBrs, and tb

Bops Driving . .

'i Locomottra Sparks, .

Static! by GnpUe end Algebnic Hcthodg 8yd,

Joub'i Hachlnc Doicn :

P»it L— Eioem»tic» of IhcWnBrr 8to

PaniL — Fonn, Stnuph, ud Pi-opoitioni al Puu 8n)

EetT's Pont aod Power TriainiiulDn 8to

I^niii'i Applied Blecbuiu Sro

HacCotd'i Einematici; or, PracUcal Uechaiium 8io

VelocitT DUgnmi* giro

Hiiuci'b Tgcbolcal UEchonlcs. Svo,

Hammaa'B Teit-book on Ibe Hechanlci of Uaterlali

• Hichie'i Elemion of Analytical Hscbaoict

Rtaian's LocomotiTei: Simple, CDm[Kiuad,aiid Elecbdc

fieid'i CaiUBc in Mecttanlcal Dianlog . ,

Teit-book ot Hcchanlcal Drawing and Elementir? Uacbine D>d|a..Svo,

Ricbards'i CompreBscd Air

RoliinBon's Principlns ol M«hani«m

Smith'! FieBs-workiue ol Hntais

Spanglcr, Grei

Animal ai ■ Hachine t

Vanen'i Elements of Ma

Weiibacb'i Kjoematlcs

Kieln.)

:id Prime Motor, and ttie Lawi of Eoi
blD( Conitmetion and Drawloe....
ind Eli« Powu of Trantmluion.

I

nalrilcBl UKbanln..

The World's Columbian Eiposltion ol rSpj

METAI.LDHGY.

^^^^^ EBlealon'a Metallurgy of Silver, Gold, and Mercury:

^^^^^H VoL n.—Gold and Mercury

^^^^^B >* Iles'i Lead-uneHlnc. (PaBtage g ceati addiHonaL) iii

^^^^^^ ICmp'b Cast Iron

^^^^^ Sunhordt'B Practice ol Ore Dresilng In Europe (

^B Le Chatelier'B Bigh-ieniperature MeiuuremeDti, (Boudouard— Bur(en.).i

H MelcBlf'i SteeL A Uinual for Sleel-uun ti:

H Smith's MaterialB of Machine! Ii:

^B TharstDn's Material! of EDgineeriiiE. lo Three Parti t

H Part IL— Iron and Steel t

H Fan IIL — A Treallie on BraBBet, BronieB, and Other Alloys and ttyiir

H Hike

^B Sarr

H Boyd

I

Hike 'i Modem Electrolytic Copper Refinlni Sto,

MIKERALOGY.

. DeBcrlptlon of Minerals of Commercial Value. Oblone, c

ourcai of SouthwMi Virginia

Map of Southwe!! Virginia Pool

■utb's Hanua] ol DetennlnmtiT« HinerolDfy. (PonficMO. '----.-. ».

iBStm'i Calaloeui el Hiiiciiili Sto, piper,

Cloth,

Dittioo«ty of Ihe Hboicsb of Uinccali 8yo

uu'l ETStem of MtncralogT. Laree Sto, half loatliFr.

Pint Appcndii to Daoi's Hew "STttam of SOiieiaJoiy." Laige Bto

Teit-book of Mlncraloer Sto

UineiBls aad How to Study Thom 1 imo

Culaloeue of Americaa Localitieg of Uinerala Larie Sto

leiBlogj and Petrographj lamo,

Acs. IShorlti/.)

t of Mmcrala and SyoonTmB. ...-...,., ......,, ,,8to,

HiMiak's Thif DetenniMtion of Roek-fonniQg MiniralB. (Smith.) Sma

MciTill'B Hoa-MEtBllic Hinecali. I.SIiiirtly.')

* Penfleld's Holes on DelerminalLTe Minoralogy and Redord of Mioeral

Hanual dj
Esklc's Mineral Ta
Eglenon's CaUlog

i Wcro

It Minerals sod

Beaid't Ventilation of Mines

Boyd's Kesourees of Southwest VirEinJa

Map of Southwest Virginia Pocket-I

■ DrinlcEr's Tunneling, Explosive Compounds, and Rock Drills.

4lo,hBlf

Ebsler's Modern High Eiplosivea

Fowler's Sewage Worka Analyses

Goodyeart Coal-mines oi the Western Coast of the Dnited States. ,

Ihlsong'a Manual of Mining

•• lles'i Lead-smelting. (Postage gc. addiCiooal )

Eunhudl'g Practice of Ore Dressing In Europe

□ide PiDi

Treatise on Practical and Theoretical Uiiie VeatUalion

SAHITARY SCIEHCE.

Copeland'a Manual of Bftcteriology. (/n prtparalirm.)
Fotwell's Sewerage. (DeEignloE, Construction and Uaintanani

Wale [-supply Engineering

Fuertes's Water and Pubhc Health

Water-filtratioa Works. ,

Gerhard's Guide to Sanitary House- inspectloD

Goodrich's Economical Disposal of Town's Refuse

Haien's Filtration of Public WMer-supplies

Kiented's Sewage Disposal

Leach'E The Inapection and Aualysis of Food with SpecUl Reft

-supply. (Considered Principally from a Sa

3d Edition, BewritlBO .

n of Water. (Chemical and BaeterlologlcaL) .

J

menti of Sanitarr Engineerinj . .
-sopplj. (Considernl Mainly from ■

<i883,)

Ogden's Sewer Delign

■Price') Bandbook on SanltiUoa

RicbardB'i CciC of Food. A Study in DleUri«

Cost of Uvint BB Uodiaed by Ssnlluy Scienca . . .
Richards and Woodmiu'i Air, Watar, and Food b

• Blcbarils aod WiUlaou't Tbe Dietary Computer

Rideal'i Sewage and Baclerlsl Puriflcation of Sewage.

Tumeaure and RiuwU'a PubUc Water-suppliei

Wbipple'i Uicroicopy ol Drinldog-water

WoodbuU's Hglel and Military Hygieae

k SmiUtry SMod-

. 3 SO

I 3 50

mSCEUAHEOaS.

eological Guide-book
'cnallonal Congicu

tion.DlcailtblliCy.and 5aliitive Value of Food. Uonaud cl

the Preeenl Tbeoty of Souod... it

irr of Reneselaei Polylectaalc loitilDta, 1814^1894. Small Svo, .
.monailied Hew Teilament Large 8vo, :

>e Diaeau

'b Important QueitioQ in Metrology ^, ........... , 8va

orld'aColumbitaEipoeitioo ol 1893. 4(0

3ter and AikloBoo. Small Bosplials, Eitabllabmeat aad UalnMuaoce
and Sugieationa for Bospital Arcbitecture, wltb Plaoi for a Small
Hoapital lamo, 1

HEBREW AND CHALDEE TEXT-BOOKS.

■mar of tbe Hebrew LanB:iiact, ...-.->.-,>.■.,,..•*.--

Qtaenjui'g Hebrew and ChaJdee LeilcoD to Iha Old TeOamenl Scripttint.

(TteggDea.) Small 4ta, ball morocco, ■

LatteriB'i Hebrew Bible Bto. :